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PCI Express® Card Electromechanical

Specification Revision 2.0

April 11, 2007

PCI EXPRESS CARD ELECTROMECHANICAL SPECIFICATION, REV. 2.0

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Revision Revision History Date

1.0 Initial release. 7/22/2002

1.0a Incorporated WG Errata C1-C7 and E1. 4/15/2003

1.1 Incorporated approved Errata and ECNs. 03/28/2005

2.0 Added support for 5 GT/s data rate. 4/11/2007

PCI-SIG® disclaims all warranties and liability for the use of this document and the information contained herein and assumes no responsibility for any errors that may appear in this document, nor does PCI-SIG make a commitment to update the information contained herein.

Contact the PCI-SIG office to obtain the latest revision of the specification.

Questions regarding this specification or membership in PCI-SIG may be forwarded to:

Membership Services www.pcisig.com E-mail: [email protected] Phone: 503-619-0569 Fax: 503-644-6708

Technical Support [email protected]

DISCLAIMER This PCI Express Card Electromechanical Specification is provided “as is” with no warranties whatsoever, including any warranty of merchantability, noninfringement, fitness for any particular purpose, or any warranty otherwise arising out of any proposal, specification, or sample. PCI-SIG disclaims all liability for infringement of proprietary rights, relating to use of information in this specification. No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted herein.

PCI, PCI Express, PCIe, and PCI-SIG are trademarks or registered trademarks of PCI-SIG.

All other product names are trademarks, registered trademarks, or service marks of their respective owners.

Copyright © 2002-2007 PCI-SIG

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Contents

1. INTRODUCTION....................................................................................................................9 1.1. TERMS AND DEFINITIONS ..................................................................................................... 9 1.2. REFERENCE DOCUMENTS ................................................................................................... 10 1.3. SPECIFICATION CONTENTS................................................................................................. 11 1.4. OBJECTIVES............................................................................................................................. 11 1.5. ELECTRICAL OVERVIEW ..................................................................................................... 12 1.6. MECHANICAL OVERVIEW ................................................................................................... 13

2. AUXILIARY SIGNALS........................................................................................................15 2.1. REFERENCE CLOCK............................................................................................................... 16

2.1.1. Low Voltage Swing, Differential Clocks .................................................................... 16 2.1.2. Spread Spectrum Clocking (SSC)............................................................................... 17 2.1.3. REFCLK AC Specifications........................................................................................ 18 2.1.4. REFCLK Phase Jitter Specification For 2.5 GT/s Signaling Support ....................... 21 2.1.5. REFCLK Phase Jitter Specification For 5 GT/s Signaling Support .......................... 22

2.2. PERST# SIGNAL ...................................................................................................................... 22 2.2.1. Initial Power-Up (G3 to S0)....................................................................................... 22 2.2.2. Power Management States (S0 to S3/S4 to S0) .......................................................... 23 2.2.3. Power Down............................................................................................................... 24

2.3. WAKE# SIGNAL ...................................................................................................................... 26 2.4. SMBUS (OPTIONAL)............................................................................................................... 29

2.4.1. Capacitive Load of High-power SMBus Lines ........................................................... 29 2.4.2. Minimum Current Sinking Requirements for SMBus Devices.................................... 30 2.4.3. SMBus “Back Powering” Considerations ................................................................. 30 2.4.4. Power-on Reset .......................................................................................................... 30

2.5. JTAG PINS (OPTIONAL) ......................................................................................................... 31 2.6. AUXILIARY SIGNAL PARAMETRIC SPECIFICATIONS................................................... 32

2.6.1. DC Specifications ....................................................................................................... 32 2.6.2. AC Specifications ....................................................................................................... 33

3. HOT INSERTION AND REMOVAL..................................................................................35 3.1. SCOPE .................................................................................................................................... 35 3.2. PRESENCE DETECT................................................................................................................ 35

4. ELECTRICAL REQUIREMENTS .....................................................................................37 4.1. POWER SUPPLY REQUIREMENTS ...................................................................................... 37 4.2. POWER CONSUMPTION ........................................................................................................ 38 4.3. POWER SUPPLY SEQUENCING............................................................................................ 39 4.4. POWER SUPPLY DECOUPLING............................................................................................ 40 4.5. ELECTRICAL TOPOLOGIES AND LINK DEFINITIONS .................................................... 40

4.5.1. Topologies .................................................................................................................. 40 4.5.2. Link Definition............................................................................................................ 42

4.6. ELECTRICAL BUDGETS ........................................................................................................ 43 4.6.1. AC Coupling Capacitors ............................................................................................ 44 4.6.2. Insertion Loss Values (Voltage Transfer Function) ................................................... 44 4.6.3. Jitter Values................................................................................................................ 44 4.6.4. Crosstalk..................................................................................................................... 46

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4.6.5. Lane-to-Lane Skew..................................................................................................... 47 4.6.6. Equalization ............................................................................................................... 47 4.6.7. Skew within the Differential Pair ............................................................................... 47 4.6.8. Differential Data Trace Impedance ........................................................................... 48 4.6.9. Differential Data Trace Propagation Delay .............................................................. 48

4.7. EYE DIAGRAMS AT THE ADD-IN CARD INTERFACE..................................................... 49 4.7.1. Add-in Card Transmitter Path Compliance Eye Diagram at 2.5 GT/s ...................... 49 4.7.2. Add-in Card Transmitter Path Compliance Eye Diagrams at 5 GT/s ....................... 50 4.7.3. Add-in Card Minimum Receiver Path Sensitivity Requirements at 2.5 GT/s ............. 52 4.7.4. Add-in Card Minimum Receiver Path Sensitivity Requirements at 5 GT/s ................ 53 4.7.5. System Board Transmitter Path Compliance Eye Diagram at 2.5 GT/s .................... 55 4.7.6. System Board Transmitter Path Compliance Eye Diagram at 5 GT/s ....................... 56 4.7.7. System Board Minimum Receiver Path Sensitivity Requirements at 2.5 GT/s ........... 59 4.7.8. System Board Minimum Receiver Path Sensitivity Requirements at 5 GT/s .............. 60

5. CONNECTOR SPECIFICATION.......................................................................................63 5.1. CONNECTOR PINOUT ............................................................................................................ 63 5.2. CONNECTOR INTERFACE DEFINITIONS........................................................................... 68 5.3. SIGNAL INTEGRITY REQUIREMENTS AND TEST PROCEDURES ................................ 72

5.3.1. Signal Integrity Requirements .................................................................................... 72 5.3.2. Signal Integrity Requirements and Test Procedures for 2.5 GT/s Support ............... 72 5.3.3. Signal Integrity Requirements and Test Procedures for 5 GT/s Support ................... 75

5.3.3.1 Test Fixture Requirements ...................................................................... 77 5.4. CONNECTOR ENVIRONMENTAL AND OTHER REQUIREMENTS ................................ 77

5.4.1. Environmental Requirements ..................................................................................... 77 5.4.2. Mechanical Requirements .......................................................................................... 79 5.4.3. Current Rating Requirement ...................................................................................... 80 5.4.4. Additional Considerations.......................................................................................... 80

6. ADD-IN CARD FORM FACTORS AND IMPLEMENTATION ....................................83 6.1. ADD-IN CARD FORM FACTORS........................................................................................... 83 6.2. CONNECTOR AND ADD-IN CARD LOCATIONS ............................................................... 94 6.3. CARD INTEROPERABILITY .................................................................................................. 99

A. INSERTION LOSS VALUES (VOLTAGE TRANSFER FUNCTION) (INFORMATIONAL ONLY) .............................................................................................101

ACKNOWLEDGEMENTS ......................................................................................................105

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Figures FIGURE 1-1: VERTICAL EDGE-CARD CONNECTOR ................................................................. 13 FIGURE 1-2: EXAMPLE SERVER I/O BOARD WITH PCI EXPRESS SLOTS ON A RISER ..... 13 FIGURE 2-1: DIFFERENTIAL REFCLK WAVEFORM ................................................................. 16 FIGURE 2-2: EXAMPLE CURRENT MODE REFERENCE CLOCK SOURCE TERMINATION17 FIGURE 2-3: SINGLE-ENDED MEASUREMENT POINTS FOR ABSOLUTE CROSS POINT

AND SWING ............................................................................................................................. 19 FIGURE 2-4: SINGLE-ENDED MEASUREMENT POINTS FOR DELTA CROSS POINT.......... 19 FIGURE 2-5: SINGLE-ENDED MEASUREMENT POINTS FOR RISE AND FALL TIME

MATCHING............................................................................................................................... 20 FIGURE 2-6: DIFFERENTIAL MEASUREMENT POINTS FOR DUTY CYCLE AND PERIOD 20 FIGURE 2-7: DIFFERENTIAL MEASUREMENT POINTS FOR RISE AND FALL TIME.......... 20 FIGURE 2-8: DIFFERENTIAL MEASUREMENT POINTS FOR RINGBACK ............................. 20 FIGURE 2-9: REFERENCE CLOCK SYSTEM MEASUREMENT POINT AND LOADING ....... 21 FIGURE 2-10: POWER UP ................................................................................................................ 23 FIGURE 2-11: POWER MANAGEMENT STATES......................................................................... 24 FIGURE 2-12: OUT-OF-TOLERANCE THRESHOLD WINDOWS ............................................... 25 FIGURE 2-13: POWER DOWN......................................................................................................... 25 FIGURE 2-14: WAKE# RISE AND FALL TIME MEASUREMENT POINTS............................... 33 FIGURE 3-1: PRESENCE DETECT IN A HOT-PLUG ENVIRONMENT...................................... 36 FIGURE 4-1: PCI EXPRESS ON THE SYSTEM BOARD............................................................... 41 FIGURE 4-2: PCI EXPRESS CONNECTOR ON SYSTEM BOARD WITH AN ADD-IN CARD. 41 FIGURE 4-3: PCI EXPRESS CONNECTOR ON A RISER CARD WITH AN ADD-IN CARD .... 42 FIGURE 4-4: LINK DEFINITION FOR TWO COMPONENTS ...................................................... 43 FIGURE 4-5: JITTER BUDGET ........................................................................................................ 44 FIGURE 4-6: ADD-IN CARD TRANSMITTER PATH COMPLIANCE EYE DIAGRAM............ 50 FIGURE 4-7: ADD-IN CARD TRANSMITTER PATH COMPLIANCE EYE DIAGRAM............ 52 FIGURE 4-8: REPRESENTATIVE COMPOSITE EYE DIAGRAM FOR ADD-IN CARD

RECEIVER PATH COMPLIANCE .......................................................................................... 53 FIGURE 4-9: REPRESENTATIVE COMPOSITE EYE DIAGRAM FOR ADD-IN CARD

RECEIVER PATH COMPLIANCE .......................................................................................... 54 FIGURE 4-10: SYSTEM BOARD TRANSMITTER PATH COMPOSITE COMPLIANCE EYE

DIAGRAM................................................................................................................................. 55 FIGURE 4-11: TWO PORT MEASUREMENT FUNCTIONAL BLOCK DIAGRAM.................... 56 FIGURE 4-12: SYSTEM BOARD TRANSMITTER PATH COMPOSITE COMPLIANCE EYE

DIAGRAM................................................................................................................................. 58 FIGURE 4-13: REPRESENTATIVE COMPOSITE EYE DIAGRAM FOR SYSTEM BOARD

RECEIVER PATH COMPLIANCE .......................................................................................... 61 FIGURE 5-1: CONNECTOR FORM FACTOR................................................................................. 68 FIGURE 5-2: RECOMMENDED FOOTPRINT................................................................................ 69 FIGURE 5-3: ADD-IN CARD EDGE-FINGER DIMENSIONS....................................................... 70 FIGURE 5-4: ILLUSTRATION OF ADJACENT PAIRS ................................................................. 75 FIGURE 5-5: CONTACT RESISTANCE MEASUREMENT POINTS............................................ 78 FIGURE 6-1: STANDARD HEIGHT PCI EXPRESS ADD-IN CARD WITHOUT THE I/O

BRACKET ................................................................................................................................. 84 FIGURE 6-2: STANDARD HEIGHT PCI EXPRESS ADD-IN CARD WITH THE I/O BRACKET

AND CARD RETAINER........................................................................................................... 85 FIGURE 6-3: ADDITIONAL FEATURE AND KEEPOUTS ON THE X16 GRAPHICS CARD ... 86 FIGURE 6-4: STANDARD ADD-IN CARD I/O BRACKET ........................................................... 87

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FIGURE 6-5: BRACKET DESIGN WITH THE MOUNTING TABS MOUNTED ON THE PRIMARY SIDE OF THE ADD-IN CARD.............................................................................. 88

FIGURE 6-6: ADD-IN CARD RETAINER ....................................................................................... 89 FIGURE 6-7: LOW PROFILE PCI EXPRESS ADD-IN CARD WITHOUT THE I/O BRACKET . 90 FIGURE 6-8: LOW PROFILE PCI EXPRESS ADD-IN CARD WITH THE I/O BRACKET ......... 91 FIGURE 6-9: LOW PROFILE I/O BRACKET.................................................................................. 92 FIGURE 6-10: FULL HEIGHT I/O BRACKET FOR LOW PROFILE CARDS .............................. 93 FIGURE 6-11: EXAMPLE OF A PC SYSTEM IN MICROATX FORM FACTOR ........................ 94 FIGURE 6-12: INTRODUCTION OF A PCI EXPRESS CONNECTOR IN A MICROATX

SYSTEM .................................................................................................................................... 95 FIGURE 6-13: MORE PCI EXPRESS CONNECTORS ARE INTRODUCED ON A MICROATX

SYSTEM BOARD ..................................................................................................................... 96 FIGURE 6-14: PCI EXPRESS CONNECTOR LOCATION IN A MICROATX SYSTEM WITH

ONE PCI EXPRESS CONNECTOR ......................................................................................... 97 FIGURE 6-15: PCI EXPRESS CONNECTOR LOCATION IN A MICROATX SYSTEM WITH

TWO PCI EXPRESS CONNECTORS ...................................................................................... 98 FIGURE 6-16: CARD ASSEMBLED IN CONNECTOR.................................................................. 99 FIGURE A-1: EXAMPLE INTERCONNECT TERMINATED AT THE CONNECTOR

INTERFACE ............................................................................................................................ 101 FIGURE A-2: INSERTION LOSS BUDGETS ................................................................................ 102

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Tables TABLE 2-1: REFCLK DC SPECIFICATIONS AND AC TIMING REQUIREMENTS.................. 18 TABLE 2-2: MAXIMUM ALLOWED PHASE JITTER WHEN APPLIED TO FIXED FILTER

CHARACTERISTIC.................................................................................................................. 22 TABLE 2-3: AUXILIARY SIGNAL DC SPECIFICATIONS - PERST#, WAKE#, AND SMBUS 32 TABLE 2-4: POWER SEQUENCING AND RESET SIGNAL TIMINGS ....................................... 33 TABLE 4-1: POWER SUPPLY RAIL REQUIREMENTS................................................................ 37 TABLE 4-2: ADD-IN CARD POWER DISSIPATION..................................................................... 38 TABLE 4-3: TOTAL SYSTEM JITTER BUDGET FOR 2.5 GT/S SIGNALING............................ 45 TABLE 4-4: ALLOCATION OF INTERCONNECT JITTER BUDGET FOR 2.5 GT/S

SIGNALING .............................................................................................................................. 45 TABLE 4-5: TOTAL SYSTEM JITTER BUDGET FOR 5 GT/S SIGNALING............................... 46 TABLE 4-6: ALLOWABLE INTERCONNECT LANE-TO-LANE SKEW..................................... 47 TABLE 4-7: ADD-IN CARD TRANSMITTER PATH COMPLIANCE EYE REQUIREMENTS AT

2.5 GT/S ..................................................................................................................................... 49 TABLE 4-8: ADD-IN CARD TRANSMITTER PATH COMPLIANCE EYE REQUIREMENTS AT

5 GT/S AND 3.5 DB DE-EMPHASIS....................................................................................... 50 TABLE 4-9: ADD-IN CARD JITTER REQUIREMENTS FOR 5 GT/S SIGNALING AT 3.5 DB

DE-EMPHASIS.......................................................................................................................... 51 TABLE 4-10: ADD-IN CARD TRANSMITTER PATH COMPLIANCE EYE REQUIREMENTS

AT 5 GT/S AT 6.0 DB DE-EMPHASIS.................................................................................... 51 TABLE 4-11: ADD-IN CARD JITTER REQUIREMENTS FOR 5 GT/S SIGNALING AT 6.0 DB

DE-EMPHASIS.......................................................................................................................... 52 TABLE 4-12: ADD-IN CARD MINIMUM RECEIVER PATH SENSITIVITY REQUIREMENTS

AT 2.5 GT/S ............................................................................................................................... 52 TABLE 4-13: ADD-IN CARD MINIMUM RECEIVER PATH SENSITIVITY REQUIREMENTS

AT 5 GT/S .................................................................................................................................. 53 TABLE 4-14: SYSTEM BOARD TRANSMITTER PATH COMPLIANCE EYE REQUIREMENTS

AT 2.5 GT/S ............................................................................................................................... 55 TABLE 4-15: SYSTEM BOARD TRANSMITTER PATH COMPLIANCE EYE REQUIREMENTS

AT 5 GT/S .................................................................................................................................. 58 TABLE 4-16: SYSTEM BOARD JITTER REQUIREMENTS FOR 5 GT/S SIGNALING ............. 59 TABLE 4-17: SYSTEM BOARD MINIMUM RECEIVER PATH SENSITIVITY

REQUIREMENTS AT 2.5 GT/S ............................................................................................... 59 TABLE 4-18: SYSTEM BOARD MINIMUM RECEIVER PATH SENSITIVITY

REQUIREMENTS AT 5 GT/S FOR A LINK THAT OPERATES WITH 3.5 DB DE-EMPHASIS ................................................................................................................................ 60

TABLE 4-19: SYSTEM BOARD MINIMUM RECEIVER PATH SENSITIVITY REQUIREMENTS AT 5 GT/S FOR A LINK THAT OPERATES WITH 6.0 DB DE-EMPHASIS ................................................................................................................................ 60

TABLE 5-1: PCI EXPRESS CONNECTORS PINOUT .................................................................... 63 TABLE 5-2: SIGNAL INTEGRITY REQUIREMENTS AND TEST PROCEDURES FOR 2.5 GT/S

SUPPORT .................................................................................................................................. 73 TABLE 5-3: SIGNAL INTEGRITY REQUIREMENTS AND TEST PROCEDURES FOR 5 GT/S

SUPPORT .................................................................................................................................. 76 TABLE 5-4: TEST DURATIONS ...................................................................................................... 78 TABLE 5-5: MECHANICAL TEST PROCEDURES AND REQUIREMENTS .............................. 79 TABLE 5-6: END OF LIFE CURRENT RATING TEST SEQUENCE ............................................ 80

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TABLE 5-7: ADDITIONAL REQUIREMENTS ............................................................................... 80 TABLE 6-1: ADD-IN CARD SIZES.................................................................................................. 83 TABLE 6-2: CARD INTEROPERABILITY...................................................................................... 99 TABLE A-1: ALLOCATION OF INTERCONNECT PATH INSERTION LOSS BUDGET FOR 2.5

GT/S SIGNALING................................................................................................................... 102

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1. Introduction This specification is a companion for the PCI Express Base Specification, Revision 2.0. Its primary focus is the implementation of an evolutionary strategy with the current PCI™ desktop/server mechanical and electrical specifications. The discussions are confined to ATX or ATX-based form factors. Other form factors, such as PCI Express® Mini Card are covered in other separate specifications. 5

1.1. Terms and Definitions add-in card A card that is plugged into a connector and mounted in a chassis slot.

ATX A system board form factor. Refer to the ATX Specification, Revision. 2.2.

ATX-based form factor Refers to the form factor that does not exactly conform to the 10 ATX specification, but uses the key features of the ATX, such as the slot spacing, I/O panel definition, etc.

Auxiliary signals Signals not required by the PCI Express architecture but necessary for certain desired functions or system implementation, for example, the SMBus signals. 15

Basic bandwidth Contains one PCI Express Lane

x1, x2, x4, x8, x12, x16 x1 refers to one PCI Express Lane of basic bandwidth; x4 refers to a collection of four PCI Express Lanes; etc.

Card Interoperability Ability to plug a PCI Express card into different Link connectors and the system works, for example, plugging a PCI Express x1 20 I/O card into a x16 graphics slot.

Down-plugging Plugging a larger Link card into a smaller Link connector; for example, plugging a x4 card into a x1 connector

Evolutionary strategy A strategy to develop the PCI Express connector and card form factors within today’s chassis and system board form factor 25 infrastructure constraints.

High bandwidth Supports larger number of PCI Express Lanes, such as a x16 card or connector.

Hot-Plug Insertion and/or removal of a card into an active backplane or system board as defined in PCI Standard Hot-Plug Controller and 30 Subsystem Specification, Revision. 1.0. No special card support is required.

Hot swap Insertion and/or removal of a card into a passive backplane. The card must satisfy specific requirements to support Hot swap.

Link A collection of one or more PCI Express Lanes

1

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Low profile card An add-in card whose height is no more than 68.90 mm (2.731 inches)

microATX An ATX-based system board form factor. Refer to the microATX Motherboard Interface Specification, Revision 1.2.

PCI Express Mini Card PCI Express for mobile form factor, similar to Mini PCI 5

PCI Express Lane One PCI Express Lane contains two differential lines for Transmitter and two differential lines for Receiver. A by-N Link is composed of N Lanes.

Receiver path The path from the connector to the receiver for a differential data pair (system) or the edge finger to the receiver (add-in card). 10

sideband signaling A method for signaling events and conditions using physical signals separate from signals forming the Link between two components.

Standard height card An add-in card whose height is no more than 111.15 mm (4.376 inches) 15

Transmitter path The path from the transmitter to the connector for a differential data pair (system) or the transmitter to the edge finger (add-in card).

Up-plugging Plugging a smaller Link card into a larger Link connector; for example, plugging a x1 card into a x4 connector

wakeup A mechanism used by a component to request the reapplication of 20 main power when in the L2 Link state. Two such mechanisms are defined in the PCI Express Base Specification, Revision 2.0: Beacon and WAKE#. This specification requires the use of WAKE# on any add-in card or system board that supports wakeup functionality.

1.2. Reference Documents This specification references the following documents: 25

PCI Express Base Specification, Revision 2.0 PCI Local Bus Specification, Revision 3.0 PCI Express Jitter Modeling PCI Express Jitter and BER ATX Specification, Revision 2.2 30

microATX Motherboard Interface Specification, Revision 1.2 SMBus Specification, Revision 2.0 JTAG Specification (IEEE1149.1) PCI Standard Hot-Plug Controller and Subsystem Specification, Revision 1.0 Compact PCI Hot Swap Specification 35

EIA-364-1000.01: Environmental Test Methodology for Assessing the Performance of Electrical Connectors and Sockets Used in Business Office Applications EIA-364: Electrical Connector/Socket Test Procedures Including Environmental Classifications

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1.3. Specification Contents This specification contains the following information:

Auxiliary signals

Add-in card hot insertion and removal

Power delivery

Add-in card electrical budget 5

Connector specification

Card form factors and implementation

1.4. Objectives The objectives of this specification are:

Support 5 GT/s data rate (per direction)

Support 2.5 GT/s data rate (per direction) 10

Enable Hot-Plug and hot swap where they are needed

Leverage desktop and server commonality

Facilitate smooth transitions

Allow co-existence of both PCI and PCI Express add-in cards

No chassis or other PC infrastructure changes 15

Forward looking for future scalability

Extensible for future bandwidth needs

Allows future evolution of PC architecture

Maximize card interoperability for user flexibility

Low cost 20

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1.5. Electrical Overview The electrical part of this specification covers auxiliary signals, hot insertion and removal, power delivery, and add-in card interconnect electrical budgets for the evolutionary strategy. The PCI Express Transmitter and Receiver electrical requirements are specified in the PCI Express Base Specification, Revision 2.0.

Besides the signals that are required to transmit/receive data on the PCI Express interface, there are 5 also signals that may be necessary to implement the PCI Express interface in a system environment, or to provide certain desired functions. These signals are referred to as the auxiliary signals. They include:

Reference clock (REFCLK), must be supplied by the system (see Section 2.1.1)

Add-in card presence detect pins (PRSNT1# and PRSNT2#), required 10

PERST#, required

JTAG, optional

SMBus, optional

Wake (WAKE#), required only if the device/system supports wakeup

+3.3Vaux, optional 15

REFCLK, JTAG, SMBus, PERST#, and WAKE# are described in Chapter 2; +3.3Vaux is described in Chapter 4; and PRSNT1# and PRSNT2# are described in Chapter 3.

Both Hot-Plug and hot swap of PCI Express add-in cards are supported, but their implementation is optional. Hot-Plug is supported with the evolutionary add-in card form factor. Hot swap is supported with other form factors and will be described in other specifications. 20

To support Hot-Plug, presence detect pins (PRSNT1# and PRSNT2#) are defined in each end of the connectors and add-in cards. Those presence detect pins are staggered on the add-in cards such that they are last-mate and first-break, detecting the presence of the add-in cards. Chapter 3 discusses the detailed implementation of PCI Express Hot-Plug.

Chapter 4 specifies the PCI Express add-in card electrical requirements, which include power 25 delivery and interconnect electrical budgets. Power is delivered to the PCI Express add-in cards via add-in card connectors, using three voltage rails: +3.3V, +3.3Vaux, and +12V. Note that the +3.3Vaux voltage rail is not required for all platforms (refer to Section 4.1 for more information on the required usage of 3.3Vaux). The maximum add-in card power definitions are based on the card size and Link widths, and are described in Section 4.2. Chapter 4 describes the interconnect 30 electrical budgets, focusing on the add-in card loss and jitter requirements.

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1.6. Mechanical Overview PCI Express can be used in many different applications in desktop, mobile, server, as well as networking and communication equipment. Consequently, multiple variations of form factors and connectors will exist to suit the unique needs of these different applications.

Figure 1-1 shows an example of the vertical edge-card PCI Express connector to be used in ATX or ATX-based systems. There will be a family of such connectors, containing one to 16 PCI Express 5 Lanes. The basic bandwidth (BW) version supports one PCI Express Lane and could be used as the replacement for the PCI connector. The high bandwidth version will support 16 PCI Express Lanes and will be used for applications that require higher bandwidth, such as graphics.

OM14739 Figure 1-1: Vertical Edge-Card Connector

Vertical edge card connectors also have applications in the server market segment. Figure 1-2 shows an example of a server configuration using a PCI Express riser card. 10

I/O Legacy Riser

PCI ExpressRiser

Rear of BoardServer

I/O Board

PCI ExpressAdd-in Card

OM14740 Figure 1-2: Example Server I/O Board with PCI Express Slots on a Riser

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Mobile applications require a right angle edge card connector. The definition of such a connector will be covered in a separate document.

For certain server and network applications there may also be a need for a Compact PCI-like PCI Express connector, or other backplane-type PCI Express connectors.

PCI Express cable connectors may also be needed for within-system applications, both internally 5 (inside the chassis) and externally (outside the chassis).

While the reality of multiple variations of PCI Express connectors and form factors is recognized, no attempt will be made to define every possible PCI Express connector and form factor variation in this specification. They will be defined later as the need arises in other specifications. This specification, instead, focuses on the vertical edge card PCI Express connectors and form factor 10 requirements by covering the following:

Connector mating interfaces and footprints

Electrical, mechanical, and reliability requirements of the connectors, including the connector testing procedures

Add-in card form factors 15

Connector and add-in card locations, as well as keep-outs on a typical desktop system board (ATX/microATX form factor)

Connector definitions and requirements are addressed in Chapter 5 and add-in card form factors and implementation are discussed in Chapter 6.

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2. Auxiliary Signals The auxiliary signals are provided on the connector to assist with certain system level functionality or implementation. These signals are not required by the PCI Express architecture. The high-speed signal voltage levels are compatible with advanced silicon processes. The optional low speed signals are defined to use the +3.3V or +3.3Vaux supplies, as they are the lowest common voltage available. 5 Most ASIC processes have high voltage (thick gate oxide) I/O transistors compatible with 3.3 V. Use of the 3.3 V supply allows PCI Express signaling to be used with existing control bus structures, avoiding a buffered set of signals and bridges between the buses.

The PCI Express connector and add-in card interfaces support the following auxiliary signals:

REFCLK-/REFCLK+ (required): low voltage differential signals. 10

Note: Requirements for REFCLK for a system board that support 5 GT/s signaling are defined in PCI Express Base Specification, Revision 2.0. A system board that supports 5 GT/s signaling must provide a reference clock that meets all requirements1 for the common clock architecture defined for the reference clock in the PCI Express Base Specification, Revision 2.0 and all the requirements defined in this specification. A system board that only support 2.5 GT/s signaling 15 must meet all reference clock requirements in this specification.

PERST# (required): indicates when the applied main power is within the specified tolerance and stable. PERST# goes inactive after a delay of TPVPERL time from the power rails achieving specified tolerance on power up.

WAKE#: an open-drain, active low signal that is driven low by a PCI Express function to re-20 activate the PCI Express Link hierarchy’s main power rails and reference clocks. It is required on any add-in card or system board that supports wakeup functionality compliant with this specification.

SMBCLK (optional): the SMBus interface clock signal. It is an open-drain signal.

SMBDAT (optional): the SMBus interface address/data signal. It is an open-drain signal. 25

JTAG (TRST#, TCLK, TDI, TDO, and TMS) (optional): the pins to support IEEE Standard 1149.1, Test Access Port and Boundary Scan Architecture (JTAG). They are included as an optional interface for PCI Express devices. IEEE Standard 1149.1 specifies the rules and permissions for designing an 1149.1-compliant IC.

PRSNT1# (required): add-in card presence detect pin. See Chapter 3 for a detailed description. 30

PRSNT2# (required): add-in card presence detect pin. See Chapter 3 for a detailed description.

1 The RMS jitter requirements are excluded. They are covered under the two port motherboard test methodology and requirements defined in this specification.

2

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Note that the SMBus interface pins are collectively optional for both the add-in card and the system board. If the optional management features are implemented, SMBCLK and SMBDAT are both required. Similarly, the JTAG pins are collectively optional. If this test mode is implemented, all the JTAG pins are required. Refer to the PCI Local Bus Specification, Revision. 3.0, Section 4.3.3 for additional system requirements related to these signals. 5

2.1. Reference Clock

2.1.1. Low Voltage Swing, Differential Clocks To reduce jitter and allow for future silicon fabrication process changes, low voltage swing, differential clocks are being used, as illustrated in Figure 2-1. The nominal single-ended swing for each clock is 0 to 0.7 V and a nominal frequency of 100 MHz ±300 PPM. The clock has a defined crossover voltage range and monotonic edges through the input threshold regions as specified in Chapter 4. 10

Tperiod

REFCLK–

REFCLK+

OM14741 Figure 2-1: Differential REFCLK Waveform

The reference clock pair is routed point-to-point to each connector from the system board according to best-known clock routing rules. The reference clock distribution to all devices must be matched to within 15 inches on the system board. The transport delay delta between the data and clock at the Receiver is assumed to be less than 10 ns. The combination of the maximum reference clock mismatch and the maximum channel length will contribute approximately 7-8 ns and the 15 remaining time is allocated to the difference in the insertion delays of the Tx and Rx devices. The routing of each signal in any given clock pair between the clock source and the connector must be well matched in length (< 0.005 inch) and appropriately spaced away from other non-clock signals to avoid excessive crosstalk.

The add-in card is not required to use the reference clock on the connector. However, the add-in 20 card is required to maintain the 600-ppm data rate matching specified in Section 4.3.7.1 of the PCI Express Base Specification, Revision 2.0. Any terminations required by the clock are to be on the system board. An example termination topology for a current-mode clock generator is shown in Figure 2-2. EMI emissions will be reduced if clocks to open sockets are shut down at the clock source. The method for detecting the presence 25 of a card in a slot and controlling the clock gating is platform specific and is not covered in this specification.

PCI EXPRESS CARD ELECTROMECHANICAL SPECIFICATION, REV. 2.0

17

A-0439

Rs

Rs

ZC-DCZC-DC

ReferenceClock

PCIExpress

Add-In CardREFCLK+

REFCLK-

Figure 2-2: Example Current Mode Reference Clock Source Termination

Termination on the add-in card is allowed, but is not covered by the specifications in Section 2.1.3. While the same measurement techniques can be used as specified in that section, Receiver termination will reduce the nominal swing and rise and fall times by half. The low input swing and low slew rates need to be validated against the clock Receiver requirements as they can cause excessive jitter in some clock input buffer designs. 5

The reference clock timings are based on nominal 100 Ω, differential pair routing with approximately .127-mm (5-mil) trace widths. This timing budget allows for a maximum add-in card trace length of 4.0 inches. No specific trace geometry, however, is explicitly defined in this specification.

2.1.2. Spread Spectrum Clocking (SSC) The reference clocks may support spread spectrum clocking. Any given system design may or may 10 not use this feature due to platform-level timing issues. The minimum clock period cannot be violated. The required method is to adjust the spread technique to not allow for modulation above the nominal frequency. This technique is often called “down-spreading.” The requirements for spread spectrum modulation rate and magnitude are given in the PCI Express Base Specification, Revision 2.0. 15

PCI EXPRESS CARD ELECTROMECHANICAL SPECIFICATION, REV. 2.0

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2.1.3. REFCLK AC Specifications All specifications in Table 2-1 are to be measured using a test configuration as described in Note 11 with a circuit as shown in Figure 2-9.

Table 2-1: REFCLK DC Specifications and AC Timing Requirements

100 MHz Input Symbol Parameter

Min Max Unit Note

Rising Edge Rate Rising Edge Rate 0.6 4.0 V/ns 2, 3

Falling Edge Rate Falling Edge Rate 0.6 4.0 V/ns 2, 3

VIH Differential Input High Voltage +150 mV 2 VIL Differential Input Low Voltage -150 mV 2 VCROSS Absolute crossing point voltage +250 +550 mV 1,4,5

VCROSS DELTA Variation of VCROSS over all rising clock edges +140 mV 1,4,9

VRB Ring-back Voltage Margin -100 +100 mV 2,12 TSTABLE Time before VRB is allowed 500 ps 2,12 TPERIOD AVG Average Clock Period Accuracy -300 +2800 ppm 2,10,13

TPERIOD ABS Absolute Period (including Jitter and Spread Spectrum modulation)

9.847 10.203 ns 2,6

TCCJITTER Cycle to Cycle jitter 150 ps 2 VMAX Absolute Max input voltage +1.15 V 1,7 VMIN Absolute Min input voltage - 0.3 V 1,8 Duty Cycle Duty Cycle 40 60 % 2

Rise-Fall Matching

Rising edge rate (REFCLK+) to falling edge rate (REFCLK-) matching

20 % 1,14

ZC-DC Clock source DC impedance 40 60 Ω 1,11

Notes: 1. Measurement taken from single ended waveform. 2. Measurement taken from differential waveform. 5 3. Measured from -150 mV to +150 mV on the differential waveform (derived from REFCLK+ minus

REFCLK-). The signal must be monotonic through the measurement region for rise and fall time. The 300 mV measurement window is centered on the differential zero crossing. See Figure 2-7.

4. Measured at crossing point where the instantaneous voltage value of the rising edge of REFCLK+ equals the falling edge of REFCLK-. See Figure 2-3. 10

5. Refers to the total variation from the lowest crossing point to the highest, regardless of which edge is crossing. Refers to all crossing points for this measurement. See Figure 2-3.

6. Defines as the absolute minimum or maximum instantaneous period. This includes cycle to cycle jitter, relative PPM tolerance, and spread spectrum modulation. See Figure 2-6.

7. Defined as the maximum instantaneous voltage including overshoot. See Figure 2-3. 15

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8. Defined as the minimum instantaneous voltage including undershoot. See Figure 2-3. 9. Defined as the total variation of all crossing voltages of Rising REFCLK+ and Falling REFCLK-.

This is the maximum allowed variance in VCROSS for any particular system. See Figure 2-4. 10. Refer to Section 4.3.7.1 of the PCI Express Base Specification, Revision 2.0 for information

regarding PPM considerations. 5 11. System board compliance measurements must use the test load card described in Figure 2-9.

REFCLK+ and REFCLK- are to be measured at the load capacitors CL. Single ended probes must be used for measurements requiring single ended measurements. Either single ended probes with math or differential probe can be used for differential measurements. Test load CL = 2 pF.

12. TSTABLE is the time the differential clock must maintain a minimum ±150 mV differential voltage after 10 rising/falling edges before it is allowed to droop back into the VRB ±100 mV differential range. See Figure 2-8.

13. PPM refers to parts per million and is a DC absolute period accuracy specification. 1 PPM is 1/1,000,000th of 100.000000 MHz exactly or 100 Hz. For 300 PPM then we have an error budget of 100 Hz/PPM * 300 PPM = 30 kHz. The period is to be measured with a frequency counter with 15 measurement window set to 100 ms or greater. The ±300 PPM applies to systems that do not employ Spread Spectrum Clocking or that use common clock source. For systems employing Spread Spectrum Clocking there is an additional 2500 PPM nominal shift in maximum period resulting from the 0.5% down spread resulting in a maximum average period specification of +2800 PPM 20

14. Matching applies to rising edge rate for REFCLK+ and falling edge rate for REFCLK-. It is measured using a ±75 mV window centered on the median cross point where REFCLK+ rising meets REFCLK- falling. The median cross point is used to calculate the voltage thresholds the oscilloscope is to use for the edge rate calculations. The Rise Edge Rate of REFCLK+ should be compared to the Fall Edge Rate of REFCLK-, the maximum allowed difference should not exceed 25 20% of the slowest edge rate. See Figure 2-5.

REFCLK–

A-0437

REFCLK+

VMAX = 1.15 V

VMIN = -0.30 V

VCROSS MAX = 550 mV

VCROSS MIN = 250 mV

Figure 2-3: Single-Ended Measurement Points for Absolute Cross Point and Swing

REFCLK–

A-0438

REFCLK+

VCROSS DELTA = 140 mV

Figure 2-4: Single-Ended Measurement Points for Delta Cross Point

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A-0434

REFCLK-

REFCLK+

REFCLK-

REFCLK+

VCROSS MEDIAN

VCROSS MEDIAN +75 mV

VCROSS MEDIAN -75 mV

VCROSS MEDIAN

TRISETFALL

Figure 2-5: Single-Ended Measurement Points for Rise and Fall Time Matching

A-0435

REFCLK+minus

0.0 V

Clock Period (Differential)

Positive DutyCycle (Differential)

Negative DutyCycle (Differential)

Figure 2-6: Differential Measurement Points for Duty Cycle and Period

A-0436

Rise Edge Rate Fall Edge Rate

REFCLK+minus

VIH = +150 mV

VIL = -150 mV

0.0 V

Figure 2-7: Differential Measurement Points for Rise and Fall Time

A-0432

TSTABLE

TSTABLE

VRB

VRB

REFCLK+minus

VIH = +150 mV

VIL = -150 mV

0.0 VVRB = +100 mV

VRB = -100 mV

Figure 2-8: Differential Measurement Points for Ringback

PCI EXPRESS CARD ELECTROMECHANICAL SPECIFICATION, REV. 2.0

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A-0433

ReferenceClock

Rs

Rs MotherboardTrace

ZC-DCZC-DC

PCI ExpressConnector

1.0" Add-In

PCI Express Add-InCard Test

REFCLK+

REFCLK-

CL = 2 pF CL = 2 pF

Figure 2-9: Reference Clock System Measurement Point and Loading

2.1.4. REFCLK Phase Jitter Specification For 2.5 GT/s Signaling Support

The phase jitter of the reference clock is to be measured using the following clock recovery function

[ ] )(*)()()( 3_*

21 sHesHsHsH delayts ⋅−= − where:

211

2

211

1 22

)(ωζω

ωζω++

+=

sss

sH ,

222

2

222

2 22

)(ωζω

ωζω++

+=

sss

sH ,

33 )(

ω+=

sssH ,

( )

( )

sdelayt

sRad

sRad

sRad

9

63

222

6

2

222

6

1

1010_

/105.1**2

/12121

105.1**2

/12121

1022**254.0

−⋅=

⋅=

++++

⋅=

++++

⋅=

=

πω

ζζ

πω

ζζ

πω

ζ

The maximum allowed magnitude of the peak-peak reference clock jitter is given in Table 2-2. For information about the maximum peak-peak phase jitter value refer to PCI Express Jitter Modeling. Multiple methods can be used to measure the maximum allowed peak-peak phase jitter value. Real 5 time sampling scopes must use a sampling rate of 20 giga-samples per second or better and take enough data to guarantee the proper bit error rate (BER). Reference clock measurements for cards

PCI EXPRESS CARD ELECTROMECHANICAL SPECIFICATION, REV. 2.0

22

should be taken with a differential, high-impedance probe using the circuit of Figure 2-9 at the load capacitors CL. Measurements for devices on the same board should be made using a differential, high-impedance probe as close to the REFCLK+ and REFCLK- input pins as possible.

Table 2-2: Maximum Allowed Phase Jitter When Applied to Fixed Filter Characteristic

BER2 Maximum Peak-Peak Phase Jitter Value (ps)

10-6 86 10-12 108

2.1.5. REFCLK Phase Jitter Specification For 5 GT/s Signaling Support

This specification does not provide a separate reference clock jitter specification for 5 GT/s signaling support. Instead, a two port methodology for simultaneously assessing the system board 5 data and reference clock is described with specified limits in Section 4.7.5.

2.2. PERST# Signal The PERST# signal is used to indicate when the power supply is within its specified voltage tolerance and is stable. It also initializes a component’s state machines and other logic once power supplies stabilize. On power up, the deassertion of PERST# is delayed 100 ms (TPVPERL) from the power rails achieving specified operating limits. Also, within this time, the reference clocks 10 (REFCLK+, REFCLK-) also become stable, at least TPERST-CLK before PERST# is deasserted. PERST# is asserted in advance of the power being switched off in a power-managed state like S3. PERST# is asserted when the power supply is powered down, but without the advanced warning of the transition.

2.2.1. Initial Power-Up (G3 to S0) As long as PERST# is active, all PCI Express functions are held in reset. The main supplies ramp 15 up to their specified levels (3.3 V and 12 V). Some time during this stabilization time, the REFCLK starts and stabilizes. After there has been time (TPVPERL) for the power and clock to become stable, PERST# is deasserted high and the PCI Express functions can start up.

On initial power-up, the hardware default state of the Active State Power Management Control field in the Link Control Register must be set to 00b. The state of this field may be changed by the 20 system BIOS or the operating system only. Other software agents are not allowed to change this field.

2 These columns provide jitter limits at different BER values on a bathtub curve. If bathtub curves are not used in jitter measurements, then the jitter limit in the 10-6 column should be used as the total jitter limit for measurements using approximately 106 unit intervals of data.

PCI EXPRESS CARD ELECTROMECHANICAL SPECIFICATION, REV. 2.0

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OM14742B

5

4

3.3 Vaux

3.3/12 Volts

PERST#

REFCLK

PCI Express Link

SMBus

JTAG

Inactive

Inactive

Inactive

Active

Active

Active

Clock Stable

Power Stable

3

21

1. 3.3Vaux stable to SMBus driven (optional). If no 3.3Vaux on platform, the delay is from +3.3V stable2. Minimum time from power rails within specified tolerance to PERST# inactive (TPVPERL)3. Minimum clock valid to PERST# inactive (TPERST-CLK)4. Minimum PERST# inactive to PCI Express link out of electrical idle5. Minimum PERST# inactive to JTAG driven (optional)

Figure 2-10: Power Up

2.2.2. Power Management States (S0 to S3/S4 to S0) If the system wants to enter S3/S4, devices are placed into D3hot states with Links in L2 prior to any power transitions at the slot. The main power and reference clock supplied to the PCI Express slot will go inactive and stay inactive until a wakeup event. As a result of the removal of main power, devices enter the D3cold state. During the D3cold state, +3.3Vaux remains at 3.3 V. On the wakeup event, the power manager restores the main power and reference clocks. As in the last section, 5 PERST# deasserts TPVPERL after the clocks and power are stable.

On resume from a D3cold state, the hardware default state of the Active State Power Management Control field in the Link Control Register must be set to 00b. The state of this field may be changed by the system BIOS or the operating system only. Other software agents are not allowed to change this field. 10

PCI EXPRESS CARD ELECTROMECHANICAL SPECIFICATION, REV. 2.0

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OM14743B

1. The PCI Express link will be put into electrical idle prior to PERST# going active.2. PERST# goes active before the power on the connector is removed.3. Clock and JTAG go inactive after PERST# goes active.4. A wakeup event resumes the power to the connector, restarts the clock, and the sequence proceeds as in power up.5. The minimum active time for PERST# is TPERST.

5

4

3.3 Vaux

3.3/12 Volts

PERST#

REFCLK

PCI Express Link

SMBus

JTAG

Inactive

ActiveActive

Active

Active

Inactive Active

Active

Active

Clock Stable

Power Stable

Clock not Stable

Power StableWakeup Event

3

2

1

Figure 2-11: Power Management States

2.2.3. Power Down A power rail (12V, 3.3V, or 3.3Vaux) is deemed to be valid or stable if the specified voltage is within the associated voltage tolerances defined in Table 4-1. Once a power rail is deemed stable, an invalid or unstable rail is defined as a rail that has dropped below the specified minimum voltage levels (e.g., below 3.00 V for the 3.3V rails). For purposes of detecting an out-of-tolerance power source, the threshold for detection should be established in a window range of no more than 5 500 mV below the specified minimum voltage level for the 3.3V and 3.3Vaux rails (i.e., 2.50 V) and 1.34 V below for the 12V rail (i.e., 9.70 V). Figure 2-12 illustrates these threshold windows.

PCI EXPRESS CARD ELECTROMECHANICAL SPECIFICATION, REV. 2.0

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A-0431

11.04 V

9.70 V

3.00 V

2.50 V

12 V Rail

3.3 V,3.3 VAUXRails

Threshold Windows

Figure 2-12: Out-of-tolerance Threshold Windows

OM14744B

1. The PCI Express link will be put into an inactive state (Device in D3hot) prior to PERST# going active, except in the case of a surprise power down.2. PERST# goes active before the power on the connector is removed.3. Clock and JTAG go inactive after PERST# goes active.4. In the case of a surprise power down, PERST# goes active TFAIL after power is no longer stable.

4

3.3 Vaux

3.3/12 Volts

PERST#

REFCLK

PCI Express Link

SMBus

JTAG

Active

Active

Active

Inactive

Active

Inactive

Clock Stable

Power Stable

2

3

1

Figure 2-13: Power Down

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2.3. WAKE# Signal The WAKE# signal is an open drain, active low signal that is driven low by a PCI Express component to reactivate the PCI Express slot’s main power rails and reference clocks. Only add-in cards that support the wake process connect to this pin. If the add-in card has wakeup capabilities, it must support the WAKE# function. Likewise, only systems that support the wakeup function need to connect to this pin, but if they do, they must fully support the WAKE# function. Such 5 systems are not required to support Beacon as a wakeup mechanism, but are encouraged to support it. If the wakeup process is used, the +3.3Vaux supply must be present and used for this function. The assertion and de-assertion of WAKE# are asynchronous to any system clock. (See Chapter 5 of the PCI Express Base Specification, Revision 2.0 for more details on PCI-compatible power management.) 10

If the WAKE# signal is supported by a slot, the signal is connected to the platform’s power management (PM) controller. WAKE# may be bused to all PCI Express add-in card connectors, forming a single input connection at the PM controller or individual connectors can have individual connections to the PM controller. Hot-Plug requires that WAKE# be isolated between connectors and driven inactive during the Hot-Plug/Hot Removal events. Refer to Section 5.1 for the 15 connector pin assignment for the WAKE# signal.

Auxiliary power (+3.3Vaux) must be used by the asserting and receiving ends of WAKE# in order to revive the hierarchy. The system vendor must also provide a pull-up on WAKE# with its bias voltage reference being supplied by the auxiliary power source in support of Link reactivation. Note that the voltage that the system board uses to terminate the WAKE# signal can be lower than the 20 auxiliary supply voltage to be compatible with lower voltage processes of the system PM controller. However, all potential drivers of the WAKE# signal must be 3.3 V tolerant.

Note: WAKE# is not PME# and should not be attached to the PCI-PME# interrupt signals. WAKE# causes power to be restored but must not directly cause an interrupt.

WAKE# has additional electrical requirements over and above standard open drain signals that 25 allow it to be shared between devices that are powered off and those that are powered on using auxiliary power for example. The additional requirements include careful circuit design to ensure that a voltage applied to the WAKE# signal network never causes damage to a component even if that particular component’s power is not applied.

Additionally, the device must ensure that it does not pull WAKE# low unless WAKE# is being 30 intentionally asserted in all cases, including when the related function is in D3cold.

This means that any component implementing WAKE# must be designed such that:

Unpowered WAKE# output circuits are not damaged if a voltage is applied to them from other powered “wire-ORed” sources of WAKE#.

When power is removed from its WAKE# generation logic, the unpowered output does not 35 present a low impedance path to ground or any other voltage.

These additional requirements ensure that the WAKE# signal network continues to function properly when a mixture of auxiliary powered, and unpowered components have their WAKE# outputs wire-ORed together. It is important to note that most commonly available open drain, and tri-state buffer circuit designs used “as is” do not satisfy the additional circuit design requirements 40 for WAKE#.

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Other requirements on the system board/add-in card designer include:

Common ground plane reference between slots/components attached to the same WAKE# signal.

Split voltage power planes (+3.3Vaux vs. +3.3V) are required if +3.3Vaux is supplied to the connector(s). 5

If +3.3Vaux is supplied to one PCI Express connector in a chassis, it must be supplied to all PCI Express connectors in that chassis.

If WAKE# is supported on one PCI Express connector in a chassis, it must be supported on all PCI Express connectors in that chassis.

If the system does not support +3.3Vaux or the wakeup function, the +3.3Vaux connector pin 10 is left open on the system board. See the PCI Bus Power Management Interface Specification, Revision 1.2 for +3.3Vaux power requirements.

+3.3Vaux voltage supply may be present even if the device is not enabled for wakeup events.

+3.3V at the PCI Express connector may be switched off by the system.

Add-in cards are permitted to generate the Beacon wakeup mechanism in addition to using the 15 WAKE# mechanism, although the system is not required to provide support for Beacon.

Note: If the add-in card uses the Beacon mechanism in addition to the WAKE# mechanism, the Beacon may be ignored by the system. Circuits that support the wake function and are intended to work in any PCI Express system must be designed to generate the Beacon on their PCI Express data lines. 20

PCI Express add-in card designers must be aware of the special requirements that constrain WAKE# and ensure that their add-in cards do not interfere with the proper operation of the WAKE# network. The WAKE# input into the system may de-assert as late as 100 ns after the WAKE# output from the function de-asserts (i.e., the WAKE# pin must be considered indeterminate for a number of cycles after it has been de-asserted). 25

The value of the pull-up resistor for WAKE# on the system board must be derived taking into account the total possible capacitance on WAKE# to ensure that WAKE# charges up to a logic high voltage level in no more than 100 ns. (See Section 4.3.3 of the PCI Local Bus Specification, Revision 3.0 for information on pull-up resistors.)

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IMPLEMENTATION NOTE Example WAKE# Circuit Design The following diagram is an example of how the WAKE# generation logic could be implemented. In this example, multiple PCI Express functions have their WAKE# signals ganged together and connected to the single WAKE# pin on the PCI Express add-in card connector. 5

The circuit driving the gate of transistor Q1 is designed to isolate the add-in card’s WAKE# network from that of the system board whenever its power source (VSOURCE) is absent.

If the card supplies power to its WAKE# logic with the PCI Express connector’s 3.3 V supply (i.e., it does not support wakeup from D3cold), then all WAKE# sources from the card will be isolated from the system board when the add-in card’s +3.3V rail is switched off. Add-in cards that support 10 wakeup from D3cold have an auxiliary power source (+3.3Vaux) to power the WAKE# logic which maintains connection of these WAKE# sources to the system board’s WAKE# signal network even when the Link hierarchy’s power (+3.3V) has been switched off.

OM14749

Card–Wake (0)#

Card–Wake (1)#

Card–Wake (n)#

U1

U1

U1

Q1U2

R2

R1

R3

DG

S Wake #

+

3.3Vaux

Q2

VSOURCE+–

System BoardAdd-in Card

Q1 = FETQ2 = Zener DiodeU1 = Open Drain BufferU2 = ComparatorVSOURCE = Voltage source for Wake# logic (either PCI Express connector Vcc

or an auxiliary voltage source)

3.3Vaux = Auxiliary voltage source provided by the system's

power supply

This example assumes that all sources of WAKE# on the add-in card are powered by either the +3.3V or +3.3Vaux (VSOURCE). If WAKE# from D3cold is supported by some, but not all of the add-15

PCI EXPRESS CARD ELECTROMECHANICAL SPECIFICATION, REV. 2.0

29

in card’s functions that generate WAKE#, the add-in card designer must ensure that there is separate isolation control for each of the WAKE# generation power sources.

PCI Express component designers could choose to integrate the “power fail detect” isolation circuitry with their WAKE# output pin physically corresponding to the source of FET Q1. Alternatively, all isolation control logic could be implemented externally on the add-in card. 5

This example is meant as a conceptual aid, and is not intended to prescribe an actual implementation.

2.4. SMBus (Optional) The optional System Management Bus (SMBus) is a two-wire interface through which various system component chips can communicate with each other and with the rest of the system. It is based on the principles of operation of I2C. 10

SMBus provides a control bus for system and power management related tasks. A system may use SMBus to pass messages to and from devices instead of tripping individual control lines. Removing the individual control lines reduces pin count. Accepting messages ensures future expandability.

With SMBus, a device can provide manufacturer information, tell the system what its model/part number is, save its state for a suspend event, report different types of errors, accept control 15 parameters, and return its status.

SMBus is described in System Management Bus (SMBus) Specification, Version 2.0. Refer to this specification for DC characteristics and all AC timings. If the system board or add-in card supports SMBus, it must adhere to additional requirements that may be found in Chapter 8 of the PCI Local Bus Specification, Revision. 3.0. 20

The system board provides pull-ups to the +3.3Vaux rail per the above specification and the components attached to these signals need to have a 3.3 V signaling tolerance.

2.4.1. Capacitive Load of High-power SMBus Lines Capacitive load for each bus line includes all pin, wire, and connector capacitances. The maximum capacitive load affects the selection of the pull-up resistor or the current source in order to meet the rise time specifications of SMBus. 25

Normally, pin capacitance is defined as the total capacitive load of one SMBus device as seen in a typical manufacturer’s data sheet. The value in the DC specifications (COUT in Table 2-3) is a recommended guideline so that two SMBus devices may, for example, be populated on an add-in card.

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2.4.2. Minimum Current Sinking Requirements for SMBus Devices

While SMBus devices used in low-power segments have practically no minimum current sinking requirements due to the low pull-up current specified for low-power segments, devices in high-power segments are required to sink a minimum current of 4 mA while maintaining the VOL(max) of 0.4 V. The requirement for 4 mA sink current determines the minimum value of the pull-up resistor RP that can be used in SMBus systems. 5

2.4.3. SMBus “Back Powering” Considerations Unpowered devices connected to either a low-power or high-power SMBus segment must provide, either within the device or through the interface circuitry, protection against “back powering” the SMBus. Unpowered devices connected to high-power segments must meet leakage specifications in Section 3.1.2.1 of the System Management Bus (SMBus) Specification, Version 2.0.

2.4.4. Power-on Reset SMBus devices detect a power-on event in one of three ways: 10

By detecting that power is being applied to the device

By PERST# being asserted

For self-powered or always powered devices, by detecting that the SMBus is active (clock and data lines have gone high after being low for more than 2.5 s)

An SMBus device must respond to a power-on event by bringing the device into an operational state 15 within tPOR, defined in Table 1 of the System Management Bus (SMBus) Specification, Version 2.0, after the device has been supplied power that is within the device’s normal operating range. Self-powered or always-powered devices, such as Smart Batteries, are not required to do a complete power-on reset but they must be in an operational state within 500 ms after the SMBus becomes active.

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2.5. JTAG Pins (Optional) The IEEE Standard 1149.1, Test Access Port and Boundary Scan Architecture, is included as an optional interface for PCI Express devices. IEEE Standard 1149.1 specifies the rules and permissions for designing an 1149.1-compliant interface. Inclusion of a Test Access Port (TAP) on an add-in card allows boundary scan to be used for testing of the card on which it is installed. The TAP is comprised of four pins (optionally five) that are used to interface serially with a TAP controller 5 within the PCI Express device.

TCK in Test Clock is used to clock state information and test data into and out of the device during operation of the TAP.

TDI in Test Data Input is used to serially shift test data and test instructions into the device during TAP operation. 10

TDO out Test Output is used to serially shift test data and test instructions out of the device during TAP operation.

TMS in Test Mode Select is used to control the state of the TAP controller in the device.

TRST# in Test Reset provides an asynchronous initialization of the 15 TAP controller. This signal is optional in IEEE Standard 1149.1. These TAP pins operate at 3.3V, the same as the other single-ended I/O signals of the PCI Express connector. The drive strength of the TDO pin is not required to be the same as other PCI Express pins. The add-in card vendor must specify TDO drive strength. The direction of these TAP pins is 20 defined from the perspective of the add-in card.

The system vendor is responsible for the design and operation of the 1149.1 serial chains (“rings”) required in the system. The signals are supplementary to the PCI Express interface. Additional information can be found in the PCI Local Bus Specification, Revision. 3.0, Section 2.2.9.

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2.6. Auxiliary Signal Parametric Specifications

2.6.1. DC Specifications

Table 2-3: Auxiliary Signal DC Specifications - PERST#, WAKE#, and SMBus

Symbol Parameter Conditions Min Max Unit Notes

VIL1 Input Low Voltage

-0.5 0.8 V 2

VIH1 Input High Voltage

2.0 Vcc3_3 + 0.5 V 2

VIL2 Input Low Voltage

-0.5 0.8 V 4

VIH2 Input High Voltage

2.1 VccSus3_3 + 0.5 V 4

VOL1 Output Low Voltage 4.0 mA 0.2 V 1, 3

VHMAX Max High Voltage Vcc3_3 + 0.5 V 3

VOL2 Output Low Voltage 4.0 mA 0.4 V 1, 4

Iin Input Leakage Current 0 to 3.3 V -10 +10 μA 2, 4

Ilkg Output Leakage Current 0 to 3.3 V -50 +50 μA 3, 5

Cin Input Pin Capacitance 7 pF 2

Cout Output (I/O) Pin Capacitance 30 pF 3,4

Notes: 1. Open-drain output a pull-up is required on the system board. There is no VOH specification for

these signals. The number given is the maximum voltage that can be applied to this pin. 2. Applies to PERST#. 3. Applies to WAKE#. 4. Applies to SMBus signals SMBDATA and SMBCLK. 5. Leakage at the pin when the output is not active (high impedance).

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2.6.2. AC Specifications

Table 2-4: Power Sequencing and Reset Signal Timings

Symbol Parameter Min Max Units Notes Figure

TPVPERL Power stable to PERST# inactive 100 ms 1 Figure 2-10

TPERST-CLK REFCLK stable before PERST# inactive 100 μs 2 Figure 2-10

TPERST PERST# active time 100 μs Figure 2-11

TFAIL Power level invalid to PERST# active 500 ns 3 Figure 2-13

TWKRF WAKE# rise – fall time 100 ns 4 Figure 2-14

Notes: 1. Any supplied power is stable when it meets the requirements specified for that power supply. 2. A supplied reference clock is stable when it meets the requirements specified for the reference clock. The

PERST# signal is asserted and de-asserted asynchronously with respect to the supplied reference clock. 3. The PERST# signal must be asserted within TFAIL of any supplied power going out of specification. 4. Measured from WAKE# assertion/de-assertion to valid input level at the system PM controller. Since WAKE# is

an open-drain signal, the rise time is dependent on the total capacitance on the platform and the system board pull-up resistor. It is the responsibility of the system designer to meet the rise time specification.

A-0338

Wake#

VIH_PMC1

VIL_PMC1

Wake#

TWKRF

Note 1: Power Management Controller input switching levels are platform dependent and are not set by this specification.

Figure 2-14: WAKE# Rise and Fall Time Measurement Points

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3. Hot Insertion and Removal In the following text, all references to mechanical elements should be interpreted in the context of the PCI Express card form factor definition, unless otherwise stated.

3.1. Scope The PCI Express specification natively supports Hot-Plug/Hot Removal of PCI Express add-in cards. However, hardware support of Hot-Plug/Hot-Removal on the system board is optional. 5 Since the PCI Express evolutionary form factor is designed as a direct PCI connector replacement and utilizes an edge card connector, the PCI Express Native Hot-Plug model is based on the standard usage model defined in the PCI Standard Hot-Plug Controller and Subsystem Specification, Revision 1.0.

The following section describes the add-in card presence detect and PCI Express Native Hot-Plug 10 signals. For a detailed explanation of the register requirements and standard usage model, see Chapter 7 of the PCI Express Base Specification, Revision 2.0.

3.2. Presence Detect The PCI Express Hot-Plug controller detects the presence of an add-in card using the PRSNT2# signal as shown in Figure 3-1. It is the responsibility of the Root Complex or the Switch to determine the presence of the add-in card and set the present bits in the appropriate register as 15 described in Chapter 7 of the PCI Express Base Specification, Revision 2.0. In addition to the Hot-Plug controller, the PRSNT2# signal is used by the system board to recognize the presence of the add-in card in order to enable the auxiliary signals: REFCLK, PERST#, SMBus group, and JTAG group. The two signals, PRSNT1# and PRSNT2#, described in Figure 3-1, are required on the PCI Express connector and must be supported by all PCI Express add-in cards. 20

Both PRSNT1# and PRSNT2# signals are required in order to detect the presence of the add-in card and to ensure that it is fully inserted in the connector. Note that the pads on the add-in card for the PRSNT1# and PRSNT2# signals are shorter than the rest of the pads in order to have about 1 ms difference of insertion time. Unused PRSNT2# pads on x4, x8, and x16 add-in cards can be either standard length or the pad can be eliminated. This scheme is used to allow the power 25 switches to isolate the power to the card during surprise removal. The mechanical details are provided in Chapter 5.

3

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Gold Fingers

OM14750A

PCI Express Add-in Card

PRSNT1# PRSNT2# Hot PlugControl Logic

PULL-UPMate Last /Break First

System Board

SystemBoard

Connector

Trace on the Add-in Card[actual trace routing is left up to the board designer]

45˚

PRSNT1# PRSNT2#

Figure 3-1: Presence Detect in a Hot-Plug Environment

It is required that all PCI Express add-in cards implement variable-length edge finger pads and tie the PRSNT1# and PRSNT2# signals together on the add-in card. There is more than one PRSNT2# pin defined in the x4, x8, and x16 PCI Express connectors; these are needed to support up-plugging. All add-in cards shall connect the PRSNT1# signal to the farthest-apart PRSNT2# signal with a single trace in between them as illustrated in Figure 3-1. For example, a x4 add-in card 5 would connect PRSNT1# with PRSNT2# on pin B31, and a x8 add-in card would connect PRSNT1# with PRSNT2# on pin B48. Refer to Table 5-1 for connector pin numbering and definition. If the system board designer chooses to implement hot-plug support, the system board must connect PRSNT1# to GND and separately connect all the PRSNT2# pins together to a single pull-up resistor, as shown in Figure 3-1. The system board designer determines the pull-up resistor 10 voltage and associated use of applicable hot-plug control logic. If the system board designer chooses not to implement hot-plug support, PRSNT1# and PRSNT2# connector pins may either be left un-connected or may be grounded on the system board.

Since the x8 add-in card may plug into a x8 connector with a x4 Link only, the system board shall have the two PRSNT2# pins (B31 and B48) connected together. This is required in order to sense 15 the presence of the x8 add-in card in a x8 connector that supports a x4 Link only. See Section 6.3 for card interoperability discussions.

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4. Electrical Requirements Power delivery requirements defined in this chapter apply not only to add-in cards, but also to connectors and systems.

4.1. Power Supply Requirements All PCI Express add-in card connectors require two power rails: +12V and +3.3V, with a third, optional 3.3Vaux rail. Systems that provide PCI Express add-in card connectors are required to 5 provide both the +12V and +3.3V rails to every PCI Express add-in card connector in the system. The 3.3Vaux rail may be supplied to the PCI Express add-in card connectors at the system board designers’ discretion. However, if a system board designer does supply 3.3Vaux to the PCI Express add-in card connector, the 3.3Vaux rail must be supplied to all PCI Express add-in card connectors. In addition, as described in Chapter 2, if the platform with the PCI Express interface supports the 10 WAKE# signal, the 3.3Vaux rail (as well as the WAKE# signal) must be supplied to all PCI Express add-in card connectors.

Table 4-1 provides the required specifications for the power supply rails available at the PCI Express slots. The system designer is responsible for ensuring that the power delivered to the PCI Express connectors meets the specifications called out in Table 4-1. 15

Table 4-1: Power Supply Rail Requirements

Power Rail 10 W Slot 25 W Slot 75 W Slot +3.3V Voltage tolerance Supply Current Capacitive Load

± 9% (max) 3.0 A (max) 1000 μF (max)

± 9% (max) 3.0 A (max) 1000 μF (max)

± 9% (max) 3.0 A (max) 1000 μF (max)

+12V Voltage tolerance Supply Current Capacitive Load

± 8% 0.5 A (max) 300 μF (max)

± 8% 2.1 A (max) 1000 μF (max)

± 8% 5.5 A (max) 2000 μF (max)

4

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Power Rail 10 W Slot 25 W Slot 75 W Slot +3.3Vaux Voltage tolerance Supply Current Wakeup Enabled Non-wakeup Enabled Capacitive Load

± 9% (max) 375 mA (max) 20 mA (max) 150 μF (max)

± 9% (max) 375 mA (max) 20 mA (max) 150 μF (max)

± 9% (max) 375 mA (max) 20 mA (max) 150 μF (max)

Notes: 1. The maximum current slew rate for each add-in card shall be no more than 0.1 A/μs.

2. Each add-in card shall limit its bulk capacitance on each power rail to less than the values shown in Table 4-1.

3. System boards that support Hot-Plug add-in cards shall limit the voltage slew rate so that the 5 inrush current to the card shall not exceed the specified maximum current. This is calculated by the equation dV/dt = I/C; where: I = maximum allowed current (A) C = maximum allowed bulk capacitance (F) dV/dt = maximum allowed voltage slew rate (V/s) 10

4.2. Power Consumption This specification provides various sizes of cards for system implementation. Each card size provides support for a certain number of PCI Express lanes, and a corresponding difference in specified power consumption as shown in Table 4-2.

Table 4-2: Add-in Card Power Dissipation

X1 x4/x8 x16 Standard height 10 W1

(max) 25 W1 (max)

25 W (max) 25 W2 (max)

75 W2, 4 (max)

Low profile card3 10 W (max) 25 W (max) 25 W (max)

Notes: 1. A standard height x1 add-in card intended for desktop applications is limited in 15

length to a half-length add-in card and 10 W maximum power dissipation. A standard height x1 add-in card intended for server I/O applications with 25 W maximum power dissipation must be greater than or equal to 177.80 mm (7.0 inches) in length, but must not exceed a full-length add-in card. See Table 6-1 for add-in card size definitions. The same server I/O add-in card must, at initial 20 power-up, not exceed 10 W of power dissipation, until configured as a high power device, at which time it must not exceed 25 W of power dissipation. Refer to Chapter 6 of the PCI Express Base Specification, Revision 1.1 for information on the power configuration mechanism.

2. A standard height x16 add-in card intended for server I/O applications must limit its 25 power dissipation to 25 W. A standard height x16 add-in card intended for graphics applications must, at initial power-up, not exceed 25 W of power dissipation, until configured as a high power device, at which time it must not exceed 75 W of power dissipation. Refer to Chapter 6 of the PCI Express Base Specification, Revision 2.0 for information on the power configuration mechanism. 30

3. All low profile add-in cards are limited in length to a half-length add-in card and must not exceed the power dissipation values shown in Table 4-2.

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4. A x16 graphics card is limited to 75 W. The 75 W maximum can be drawn via the combination of +12V and +3.3V rails, but each rail draw is limited as defined in Table 4-1, and the sum of the draw on the two rails cannot exceed 75 W.

The power limits for respective connector widths, x1, x4/x8, and x16, represent the add-in card and system capacity to provide cooling for the slot. The 10 W limit assumes natural convection cooling 5 in a system that provides air exchanges. The 25 W and above add-in card power limits assume that sufficient cooling is provided to the slot by the cards in the present chassis environment. In general, the power limits above assume a chassis environment with a maximum internal temperature of 55ºC on the primary component side of the add-in card and natural convection cooling in a system that provides air exchanges. Implementations of other chassis environments should pay special attention 10 to system level thermal requirements.

PCI Express allows for higher maximum power for graphics cards than AGP. In case such a graphics card is used in a system, implementers should pay special attention to system level thermal, acoustic, structure, and power delivery requirements. To insure optimum performance, it is recommended that the system designer refer to the PCI Express Graphics Card Thermal and Mechanical 15 Guideline for Desktop Systems.

IMPLEMENTATION NOTE Software Update of the Slot Power Limit System firmware must update the slot power limit to the system's allocated value for the PCI Express add-in card (e.g., graphics) and ensure the completion of this update prior to invoking the 20 option ROM for that add-in card's PCI Express function. If the initial slot power limit value is set by hardware initialization, then any attempt by software to change that value must be verified by that software prior to initializing the add-in card. Subsequent updates by the system firmware or operating system software, if any, may only increase the slot power limit value. However, after a card is reset, the initial slot power limit value may be lower than the previous value. The maximum 25 power level for an add-in card must be assigned by the system firmware during PCI Express configuration. For graphics, the power level assigned will be dependent on the platform’s support of the PCI Express x16 Graphics 150W-ATX Specification, Revision 1.0 (including the supplemental power cable).

4.3. Power Supply Sequencing There is no specific requirement for power supply sequencing of each of the three power supply 30 rails. They may come up or go down in any order. The system, however, must assert the PERST# signal whenever any of the three power rails goes outside of the specifications provided in Table 4-1 (refer to Section 2.1.5 for specific information on the function and proper use of the PERST# signal).

Note: If a PCI Express add-in card requires power supply rail sequencing, it is the responsibility of 35 the add-in card designer to provide appropriate circuitry on the add-in card to meet any power supply rail sequencing requirements.

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4.4. Power Supply Decoupling Due to the low level signaling of the PCI Express interface, it is strongly recommended that sufficient decoupling of all power supplies be provided. This is recommended to ensure that power supply noise does not interfere with the recovery of data from a remote upstream PCI Express device. Some basic guidelines to help ensure a quiet power supply are provided below.

Note: The following are guidelines only. It is the responsibility of the add-in card designer to 5 properly test the design to ensure that add-in card circuitry does not create excessive noise on power supply or ground signals at the add-in card edge fingers.

The add-in card device decouple value should average 0.01 μF per device Vcc pin (for all devices on the add-in card).

The trace length between a decoupling capacitor and the power supply or ground via should be 10 less then 0.2 inches (5.08 mm) and be a minimum of 0.02 inches (0.508 mm) in width.

A bulk decoupling capacitor (greater than 10 μF) is recommended at the add-in card edge finger for each power supply.

A bulk decoupling capacitor (greater than 10 μF) is recommended on each power supply used within a device on the add-in card. This bulk decoupling capacitor should be in close proximity 15 to the add-in card device.

4.5. Electrical Topologies and Link Definitions The remainder of this chapter describes the electrical characteristics of PCI Express add-in cards. The electrical characteristic at the card interface is defined in terms of electrical budgets. This budget allocation decouples the electrical specification for the system designer and the card vendor and ensures successful communication between the PCI Express signal input and output Links at 20 the system board and add-in card interface. Unless otherwise noted, the specifications contained herein apply to all high-speed signals of each interface width definition. The signaling rate for encoded data is 5 GT/s, or 2.5 GT/s and the signaling is point-to-point. Requirements are called out separately for 5 GT/s and 2.5 GT/s signaling rates. A CEM device that supports the 5 GT/s rate must also support the 2.5 GT/s rate. 25

4.5.1. Topologies Three possible electrical topologies for PCI Express are:

PCI Express devices on the same system board

PCI Express devices across one connector on a system with a system board and an add-in card

PCI Express devices across two connectors on a system with a system board, a riser card, and an add-in card 30

This specification supports only the one and two connector topologies. The “PCI Express on-board” configuration is used for two-PCI Express devices on a common PCB (see Figure 4-1). Since there are no add-in cards involved in this topology, refer to the PCI Express Base Specification, Revision 2.0 for implementation of this topology.

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OM14751

PCI ExpressDevices

Figure 4-1: PCI Express on the System Board

The topology of “PCI Express with one connector” allows a plug-in PCI Express add-in card similar to a standard PCI or AGP add-in card to interface with a system board using a PCI Express vertical edge connector (Figure 4-2). In this topology, only one connector-card interface exists.

PCIConnectors

OM14766

PCI ExpressConnector, X1

PCI ExpressConnector, X16

Figure 4-2: PCI Express Connector on System Board with an Add-in Card

The topology of “PCI Express with two connectors on a riser card” allows for a plug-in PCI Express add-in card similar to a standard PCI or AGP add-in card to interface with a riser card using 5 a PCI Express connector (Figure 4-3). The riser card plugs to the system board using another riser

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connector (either PCI Express or other connector). In this topology, two connector-card interfaces exist.

I/O Legacy Riser

PCI ExpressRiser

Rear of BoardServer

I/O Board

PCI ExpressAdd-in Card

OM14753

Figure 4-3: PCI Express Connector on a Riser Card with an Add-in Card

4.5.2. Link Definition Typical PCI Express Links consist of the following:

Transmitters/Receivers on an ASIC on a system board

Package fan-in-out trace topologies 5

PCB coupled microstrip and/or striplines

Vias for layer changes

Optional proprietary PCI Express connector and riser card interface

Optional riser card with microstrip and/or stripline trace

PCI Express connector and add-in card interface 10

Coupled microstrip line and/or stripline traces on add-in card

AC-coupling capacitors

Transmitter/Receivers on an ASIC on the add-in card The electrical parameters for the Link are subdivided into two components (Figure 4-4):

Add-in card 15

System board and PCI Express connector (and riser card with associated connector if it exists)

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Transmitter and Package

Add-in CardSystem Board

Receiver and Package

PC

I Express C

onnector

Add-in CardInterconnect

System BoardInterconnect

AC CouplingCapacitors

OM14754 Figure 4-4: Link Definition for Two Components

The electrical impact of discontinuities on the Link such as via, bend, and test-points should be included in the respective components.

4.6. Electrical Budgets A budget is defined for each of the following electrical parameters associated with the Link:

AC coupling capacitors

Insertion Loss (Voltage Transfer Function) 5

Jitter

Lane-to-Lane skew

Crosstalk

Equalization

Skew within a differential pair 10

Differential data trace impedance

Differential data trace propagation delay

The electrical budgets are different for each of the two Link components:

Add-in card budget

System board and PCI Express connector budgets 15

The interconnect Link budget allocations associated with the Transmitters and Receivers differ. This is to account for any electrical characteristics the AC coupling capacitors may contribute to the Link.

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4.6.1. AC Coupling Capacitors The PCI Express add-in card and system board shall incorporate AC coupling capacitors on the Transmitter differential pair. This is to ensure blocking of the DC path between the PCI Express add-in card and the system board. The specific capacitance values are specified in the PCI Express Base Specification, Revision 2.0. Note that attenuation or jitter caused by the coupling capacitors must be accounted for as part of the budget allocation for the physical interconnect component’s path on 5 which the capacitors are mounted. Note that there may be parasitic effects associated with the component’s placement as mounted on the printed circuit board.

4.6.2. Insertion Loss Values (Voltage Transfer Function) Appendix A contains background information on maximum insertion loss assumptions that were made in computing the 2.5 GT/s eye diagram requirements. This section is provided only for information purposes. 10

4.6.3. Jitter Values The maximum jitter values in terms of percentage of Unit Interval (UI = 400 ps for 2.5 GT/s and 200 ps for 5 GT/s) are specified for the system board and the add-in card. The jitter associated with the riser card and associated proprietary connector will be part of the system board jitter budget. The jitter values are defined with respect to 100 Ω differential termination, realized as two 50 Ω resistances. These resistances are referenced to ground at the interface (see Figure 4-5). 15

Add-in CardSystem Board

PC

I Express C

onnector

OM14755A

JST JAR

JSR JAT

Figure 4-5: Jitter Budget

The total system jitter budget is derived with the assumption of a minimum Rj for each of the four budget items. This minimum Rj component is used to determine the overall system budget. The probability distribution of the Rj component is at the Bit Error Rate (BER) indicated and is Gaussian.

For any jitter distribution the total Tj must always be met at the BER. The Rj of the components 20 are independent and convolve as the root sum square. Tradeoffs of Rj and Dj are allowed, provided

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the total Tj is always met. More information on the calculation of the system budget can be found in PCI Express Jitter and BER.

Table 4-3: Total System Jitter Budget For 2.5 GT/s Signaling

Jitter Contribution Min Rj (ps) Max Dj (ps) Tj at BER 10-12 (ps)3 Tj at BER 10-6 (ps)Tx 2.8 60.6 100 87 Ref Clock 4.7 41.9 108 86 Media 0 90 90 90 Rx 2.8 120.6 160 147

Linear Total Tj: 458 410 Root Sum Square (RSS) Total Tj: 399.13 371.52

Notes:

1. RSS equation for BER 10-12 Tj = n

Dj∑ + 14.069 * 2

nRj∑

2. RSS equation for BER 10-6 Tj = nDj∑ + 9.507 * 2∑ nRj 5

Table 4-4: Allocation of Interconnect Jitter Budget For 2.5 GT/s Signaling

Jitter Parameter Jitter Budget Value (UI) Comments

PCI Express Add-in Card

JAR < 0.0575

JAT < 0.0650 Notes 1, 2

System Board and Connector

JST < 0.1675 JSR < 0.1600 Notes 1, 3

Total Jitter JT < 0.225 Note 1

Notes: 1. All values are referenced to 100 Ω, realized as two 50 Ω resistances.

The jitter budget values include all possible crosstalk impacts (near-end and far-end) and potential mismatch of the actual interconnect with respect to the 100 Ω reference load. 10

The PCI Express Base Specification, Revision 2.0 allows an interconnect jitter budget of 0.225 UI (equivalent to 90 ps for a 400 ps Unit-Interval). The allocated jitter budget values in Table 4-3 and Table 4-4 directly correlate to the eye diagram widths in Section 4.7. Tradeoffs in terms of attenuation, crosstalk, and mismatch can be 15 made within the budget allocations specified. No additional guard band is specifically allocated.

The jitter allocations are then assumed per differential pair according to the table. These allocation assumptions must also include any effects of far-end crosstalk. 20

3 This column provides jitter limits at different BER values on a bathtub curve. If bathtub curves are not used in jitter measurements, then the jitter limit in the 10-6 column should be used as the total jitter limit for measurements using approximately 106 unit intervals of data.

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2. All values are referenced to 100 Ω. The add-in card budget does not include the add-in card edge finger or connector. However, it does include potential jitter from the AC coupling capacitors on the Transmitter (TX) interconnect of the add-in card. The budget allocations generally allow for a maximum of 4-inch trace lengths for 5 differential pairs having an approximate .127-mm (5-mil) trace width. No specific trace geometry, however, is explicitly defined in this specification. The subscripts of the symbol designators, T and R, represent the Transmitter and Receiver respectively.

3. All values are referenced to 100 Ω. The system board budget includes 10 the PCI Express connector and assumes it is mated with the card edge finger. Refer to Section 5.3 for specifics on the standalone connector budget. The system board budget includes potential jitter from the AC coupling capacitors on the Transmitter (TX) interconnect on the system board. The subscripts of the symbol designators, T and R, represent 15 the Transmitter and Receiver respectively.

The total system jitter budget for 5 GT/s signaling specifies separate RJ and DJ limits for each of the four components in the jitter budget. Refer to Section 4.3.2 in the PCI Express Base Specification, Revision 2.0 for a more detailed discussion of the system jitter budget, RJ and DJ.

Table 4-5: Total System Jitter Budget For 5 GT/s Signaling

Jitter Contribution Max Dj (ps) Tj at BER 10-12 (ps) Tx 30 50 Ref Clock 0 43.6 Media 58 58 Rx 60 80

Linear Total Tj: 231.6 Root Sum Square (RSS) Total Tj: 200

Notes: 20

1. RSS equation for BER 10-12 Tj = n

Dj∑ + 14.069 * 2

nRj∑

Note: The jitter budget distributions above are used to derive the eye diagram widths as described later in this chapter. However, they are provided here only as a design guideline. Compliance measurements must actually be verified against the eye diagrams themselves as defined in Section 4.7. 25

4.6.4. Crosstalk All add-in card designs must properly account for any crosstalk that may exist among the various pairs of differential signals. Crosstalk may be either near-end (NEXT) or far-end (FEXT). Each component can have potential impact on a design and must be planned for accordingly.

Note that the total maximum crosstalk that a Receiver component in Electrical Idle is required to tolerate is < 65 mV as dictated by the Electrical Idle Detect Threshold in the PCI Express Base 30 Specification, Revision 2.0. Additionally, crosstalk between differential pairs on the add-in card will influence and impact the data signals and any subsequent loss and jitter budgets as noted in Sections 4.6.2 and 4.6.3. Note that all eye diagrams in Section 4.7 must account for any and all

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crosstalk present. In order to limit crosstalk impacts and implications, it is recommended that the add-in card limit the total amount of NEXT to a maximum of 50 mV.

All system boards interfacing with an add-in card must also properly account for crosstalk. The system board must also account for potential crosstalk that can occur on the printed circuit board as well as within the connector itself (see Section 5.3). 5

4.6.5. Lane-to-Lane Skew The skew at any point is measured using zero crossings of differential voltage of the compliance pattern, while simultaneously transmitting on all physical Lanes. The compliance pattern is defined in the PCI Express Base Specification, Revision 2.0.

Table 4-6: Allowable Interconnect Lane-to-Lane Skew

Skew Parameter Symbol Skew Values Comments Total Interconnect Skew TS 1.6 ns This does not include

Transmitter output skew, LTX-SKEW (specified in the PCI Express Base Specification, Revision 2.0). The total skew at the Receiver (ST + LTX-SKEW) is smaller than LRX-SKEW (specified in the PCI Express Base Specification, Revision 2.0) to minimize latency for this add-in card topology.

PCI Express Add-in Card AS 0.35 ns Estimates about a 2-inch trace

length delta on FR4 boards.

System Board sS 1.25 ns Estimates about a 7-inch trace

length delta on FR4 boards.

4.6.6. Equalization To reduce ISI, 3.5 dB (±0.5 dB) below the first bit de-emphasis in the Transmitter is required for the add-in card and the system board for 2.5 GT/s signaling. 6.0 dB (±0.5 dB) or 3.5 dB (±0.5 dB) 10 de-emphasis is required for the add-in card and system board for 5 GT/s signaling. For implementation details, refer to Chapter 4 in the PCI Express Base Specification, Revision 2.0.

4.6.7. Skew within the Differential Pair The skew within the differential pair gives rise to a common-mode signal component, which can, in turn, increase Electromagnetic Interference (EMI). The differential pair shall be routed such that the skew within differential pairs is less than .127 mm (5 mils) for the add-in card and .254 mm 15 (10 mils) for the system board.

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4.6.8. Differential Data Trace Impedance The PCB trace pair differential impedance for a 5 GT/s capable data pair must be in the range of 68 Ω to 105 Ω. This applies to both the add-in card and the system board.

Note: This requirement does not apply to vias, the connectors, package traces, cables, and other similar structures.

Note: Designs should still attempt to minimize the impedance discontinuities from vias, the 5 connectors, package traces, cables, and other similar structures.

IMPLEMENTATION NOTE Differential PCB Trace Impedance The PCB trace impedance requirement specified in Section 4.6.8 only applies to topologies that support 5 GT/s covered by this form factor specification that use the connector defined in this 10 form factor specification.

Specifically, the PCI Express Card Electromechanical Specification covers the following two topologies (as defined in Section 4.5.1):

PCI Express devices across one card electromechanical connector on a system with a system board and an add-in card 15

PCI Express devices across two card electromechanical connectors on a system with a system board, a riser card, and an add-in card, where the connector between the riser card and the add-in card is a card electromechanical connector.

Other topologies governed by different specifications may impose different impedance requirements or leave the impedance unspecified. 20

For example, the topology of "PCI Express devices on the same system board" does not fit within a form factor specification and hence must only follow the requirements of the PCI Express Base Specification. The PCI Express Base Specification does not define a PCB trace impedance requirement so with this topology designers can choose the PCB trace impedance that is best for their applications.

4.6.9. Differential Data Trace Propagation Delay The propagation delay for an add-in card data trace from the edge finger to the 25 Receiver/Transmitter must not exceed 750 ps.

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4.7. Eye Diagrams at the Add-in Card Interface The eye diagrams defined in this section represent the compliance eye diagrams that must be met for both the add-in card and a system board interfacing with such an add-in card. The specific measurement requirements (probe test points, calibrated system board specifics, etc.) for compliance of physical components are to be specified in the PHY Electrical Test Considerations for PCI Express Architecture document. A sample size of 106 UI is assumed for the eye diagram measurements. 5 These compliance eye diagrams with BER of 10-12 can also be used for simulation by following the guidelines explained in Section 4.6. Note: The eye diagrams specified for 5 GT/s include de-emphasis jitter affects. De-emphasis jitter is not derated in 5 GT/s measurements.

4.7.1. Add-in Card Transmitter Path Compliance Eye Diagram at 2.5 GT/s

The eye diagrams for the add-in card’s Transmitter path compliance at 2.5 GT/s are defined in Table 4-7 and Figure 4-7. 10

Table 4-7: Add-in Card Transmitter Path Compliance Eye Requirements at 2.5 GT/s

Parameter Min Max Unit Comments VTXA VTXA_d

514

360

1200

1200

mV

mV

Notes 1, 2, 5 Notes 1, 2, 5

TTXA JTXA-MEDIAN-to-MAX-JITTER

287

56.5

ps

ps

Notes 1, 3, 5 Notes 1, 4, 5

Notes: 1. An ideal reference clock without jitter is assumed for this specification. All Links

are assumed active while generating this eye diagram.

2. Transition and non-transition bits must be distinguished in order to measure compliance against the de-emphasized voltage level (VTXA_d). VTXA and VTXA_d are 15 minimum differential peak-peak output voltages.

3. TTXA is the minimum eye width. The sample size for this measurement is 106 UI. This value can be reduced to 274 ps for simulation purpose at BER 10-12.

4. JTXA-MEDIAN-to-MAX-JITTER is the maximum median-to-max jitter outlier as defined in the PCI Express Base Specification, Revision 2.0. The sample size for this 20 measurement is 106 UI. This value can be increased to 63 ps for simulation purpose at BER 10-12.

5. The values in Table 4-7 are referenced to an ideal 100 Ω differential load at the end of the interconnect path at the edge-finger boundary on the add-in card (see Figure 4-5). The eye diagram is defined and centered with respect to the jitter 25 median. Exact conditions required for verifying compliance while generating this eye diagram are given in the PHY Electrical Test Considerations for PCI Express Architecture document.

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OM14758A

TtxA

VtxA

VtxA_d

Figure 4-6: Add-in Card Transmitter Path Compliance Eye Diagram

4.7.2. Add-in Card Transmitter Path Compliance Eye Diagrams at 5 GT/s

The eye diagrams for the add-in card’s Transmitter path compliance at 5 GT/s are defined in Table 4-7, Table 4-8, Table 4-9, Table 4-10, Table 4-11, and Figure 4-7.

Table 4-8: Add-in Card Transmitter Path Compliance Eye Requirements at 5 GT/s and 3.5 dB De-emphasis

Parameter Min Max Unit Comments VTXA VTXA_d

380

380

1200

1200

mV

mV

Notes 1, 2, 4 Notes 1, 2, 4

TTXA (with crosstalk) TTXA (without crosstalk)

123

126

ps

ps

Notes 1, 3, 4

Notes: 1. An ideal reference clock without jitter is assumed for this specification. All Links

are assumed active while generating this eye diagram. The eye diagram 5 requires that CMM pattern (PCI Express Base Specification, Revision 2.0, Section 4.2.8) is being transmitted during the test.

2. Transition and non-transition bits must be distinguished in order to measure compliance against the de-emphasized voltage level (VTXA_d). VTXA and VTXA_d are minimum differential peak-peak output voltages. 10

3. TTXA is the minimum eye width. The recommended sample size for this measurement is at least 106 UI. This calculated eye width at BER 10-12 must not exceed TTXA. If the add-in card board uses non-interleaved routing, then crosstalk will be present in the measured data. If the add-in card board uses interleaved routing, then crosstalk will not be present and an adjusted minimum 15 eye width is used.

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4. The values in Table 4-8 are referenced to an ideal 100 Ω differential load at the end of an isolated 3-inch long 85 Ω differential trace behind a standard PCI Express connector. Exact conditions required for verifying compliance while generating this eye diagram are given in the PHY Electrical Test Considerations for PCI Express Architecture document. 5

The add-in card total jitter for the Transmitter + Transmitter interconnect must meet the requirements in Table 4-9 when decomposed into random and deterministic jitter.

Table 4-9: Add-in Card Jitter Requirements For 5 GT/s Signaling at 3.5 dB De-emphasis

Max Dj (ps) Tj at BER 10-12 (ps)

With crosstalk 57 77

Without crosstalk 54 74

Table 4-10: Add-in Card Transmitter Path Compliance Eye Requirements at 5 GT/s at 6.0 dB De-emphasis

Parameter Min Max Unit Comments VTXA VTXA_d

306 260

1200 1200

mV mV

Notes 1, 2, 4 Notes 1, 2, 4

TTXA (With crosstalk) TTXA (Without crosstalk)

123 126

ps ps

Notes 1, 3, 4

Notes: 1. An ideal reference clock without jitter is assumed for this specification. All Links

are assumed active while generating this eye diagram. The eye diagram 10 requires that CMM pattern (PCI Express Base Specification, Revision 2.0, Section 4.2.8) is being transmitted during the test.

2. Transition and non-transition bits must be distinguished in order to measure compliance against the de-emphasized voltage level (VTXA_d). VTXA and VTXA_d are minimum differential peak-peak output voltages. 15

3. TTXA is the minimum eye width. The recommended sample size for this measurement is at least 106 UI. This calculated eye width at BER 10-12 must not exceed TTXA. If the add-in card board uses non-interleaved routing, then crosstalk will be present in the measured data. If the add-in card board uses interleaved routing, then crosstalk will not be present and an adjusted minimum 20 eye width is used.

4. The values in Table 4-10 are referenced to an ideal 100 Ω differential load at the end of an isolated 3-inch long 85 Ω differential trace behind a standard PCI Express connector. Exact conditions required for verifying compliance while generating this eye diagram are given in the PHY Electrical Test Considerations 25 for PCI Express Architecture document.

The add-in card total jitter for the Transmitter + Transmitter interconnect must meet the requirements in Table 4-11 when decomposed into random and deterministic jitter.

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Table 4-11: Add-in Card Jitter Requirements For 5 GT/s Signaling at 6.0 dB De-emphasis

Max Dj (ps) Tj at BER 10-12 (ps) With crosstalk 57 77 Without crosstalk 54 74

OM14758A

TtxA

VtxA

VtxA_d

Figure 4-7: Add-in Card Transmitter Path Compliance Eye Diagram

4.7.3. Add-in Card Minimum Receiver Path Sensitivity Requirements at 2.5 GT/s

The minimum sensitivity values for the add-in card’s Receiver path compliance at 2.5 GT/s are defined in Table 4-12, and a representative eye diagram is shown in Figure 4-9.

Table 4-12: Add-in Card Minimum Receiver Path Sensitivity Requirements at 2.5 GT/s

Parameter Min Max Unit Comments VRXA VRXA_d

238 219

1200 1200

mV mV

Notes 1, 2, 5 Notes 1, 2, 5

TRXA JRXA-MEDIAN-to-MAX-JITTER

246 77

ps ps

Notes 1, 3, 5 Notes 1, 4, 5

Notes: 1. An ideal reference clock without jitter is assumed for this specification. All Links

are assumed active while generating this eye diagram. 5

2. Transition and non-transition bits must be distinguished in order to measure compliance against the de-emphasized voltage level (VRXA_d). VRXA and VRXA_d are differential peak-peak output voltages.

3. TRXA is the eye width. The sample size for this measurement is 106 UI. This value can be reduced to 233 ps for simulation purpose at BER 10-12. 10

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4. JRXA-MEDIAN-to-MAX-JITTER is the maximum median-to-peak jitter outlier as defined in the PCI Express Base Specification, Revision 2.0. The sample size for this measurement is 106 UI. This value can be increased to 83.5 ps for simulation purpose at BER 10-12.

5. The values in Table 4-12 are initially referenced to an ideal 100 Ω differential 5 load. The resultant values, when provided to the Receiver interconnect path of the add-in card, allow for a demonstration of compliance of the overall add-in card Receiver path. The sensitivity requirements are defined and centered with respect to the jitter median. Exact conditions required for verifying compliance against these values are given in the PHY Electrical Test Considerations for PCI 10 Express Architecture document.

OM14759A

TrxA

VrxA

VrxA_d

Figure 4-8: Representative Composite Eye Diagram for Add-in Card Receiver Path

Compliance

4.7.4. Add-in Card Minimum Receiver Path Sensitivity Requirements at 5 GT/s

The minimum sensitivity values for the add-in card’s Receiver path compliance at 5 GT/s are defined in Table 4-13, and a representative eye diagram is shown in Figure 4-9.

Table 4-13: Add-in Card Minimum Receiver Path Sensitivity Requirements at 5 GT/s

Parameter Min Max Unit Comments VRXA VRXA_d

300 300

1200 1200

mV mV

Notes 1, 2, 3 Notes 1, 2, 3

1.5 – 100 MHz RMS Jitter 3.4 ps RMS 33 kHz Refclk Residual 75 ps PP < 1.5 MHz RMS Jitter 4.2 ps RMS 1.5 – 100 MHz DJ 30 ps PP > 100 MHz DJ 27 ps PP

Notes: 1. An ideal reference clock without jitter is assumed for this specification. All Links 15

are assumed active while generating this eye diagram. The CMM pattern must be transmitted during the test.

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2. Transition and non-transition bits must be distinguished in order to measure compliance against the de-emphasized voltage level (VRXA_d). VRXA and VRXA_d are differential peak-peak output voltages.

3. The values in Table 4-13 are initially referenced to an ideal 100 Ω differential load behind 2 inches of isolated 85 Ω trace and a standard PCI Express edge 5 finger. After reference calibration, the reference fixture is removed and the add-in card to be tested is placed into a standard PCI Express connector. The resultant values, when provided to the Receiver interconnect path of the add-in card, allow for a demonstration of compliance of the overall add-in card Receiver path. The exact setup and methodology for injecting this signal into 10 the Receiver interconnect path of the add-in card are not specified. The values in Table 4-12 may need to be adjusted based on the exact test setup and methodology. For example, if the impedance of the test setup does not create the worst case mismatch that could be present with a real system board or the test setup does not provide crosstalk (only a single Lane is tested, etc) the 15 values in Table 4-12 must be adjusted accordingly.

OM14759A

TrxA

VrxA

VrxA_d

Figure 4-9: Representative Composite Eye Diagram for Add-in Card Receiver Path

Compliance

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4.7.5. System Board Transmitter Path Compliance Eye Diagram at 2.5 GT/s

The eye diagram for the system board’s Transmitter compliance at 2.5 GT/s is defined in Table 4-14 and Figure 4-12.

Table 4-14: System Board Transmitter Path Compliance Eye Requirements at 2.5 GT/s Parameter Min Max Unit Comments VTXS VTXS_d

274 253

1200 1200

mV mV

Notes 1, 2, 5 Notes 1, 2, 5

TTXS JTXS-MEDIAN-to-MAX-JITTER

246

77

ps ps

Notes 1, 3, 5 Notes 1, 4, 5

Notes: 1. An ideal reference clock without jitter is assumed for this specification. All Links

are assumed active while generating this eye diagram. 5

2. Transition and non-transition bits must be distinguished in order to measure compliance against the de-emphasized voltage level (VTXS_d). VTXS and VTXS_d are minimum differential peak-peak output voltages.

3. TTXS is the minimum eye width. The sample size for this measurement is 106 UI. This value can be reduced to 233 ps for simulation purpose at BER 10-12. 10

4. JTXS-MEDIAN-to-MAX-JITTER is the maximum median-to-max jitter outlier as defined in the PCI Express Base Specification, Revision 2.0. The sample size for this measurement is 106 UI. This value can be increased to 83.5 ps for simulation purpose at BER 10-12.

5. The values in Table 4-14 are referenced to an ideal 100 Ω differential load at the 15 end of the interconnect path at the edge-finger boundary on the add-in card when mated with a connector (see Figure 4-5). The eye diagram is defined and centered with respect to the jitter median. Exact conditions required for verifying compliance while generating this eye diagram are given in the PHY Electrical Test Considerations for PCI Express Architecture document. 20

A-0335

TtxS

VtxS

VtxS_d

Figure 4-10: System Board Transmitter Path Composite Compliance Eye Diagram

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4.7.6. System Board Transmitter Path Compliance Eye Diagram at 5 GT/s

The system board Transmitter path measurements at 5 GT/s are made using a two port measurement methodology. Figure 4-11 shows a functional block diagram for a system board and add-in card that shows the measurement points for the two port method.

A-0618

H1(s)

Tx

System Board

Rx

Add-in Card

Xtx(s)

PLL1

Latch/Driver

Xmed(s)

Xclk(s)Refclk

Test Port 1(Data)

Test Port 2(Clock)

H2(s)

H3(s)Yec(s)

Figure 4-11: Two Port Measurement Functional Block Diagram

Equations for the jitter at test port 1 and test port 2 and the eye closure at the add-in card Receiver from the test port signals are provided as follows: 5

Data Port Measurement (Test Port 1):

)()(1)()()( Eq.(1) 1 sXsXadsTesHsXsX medtxclkdm ++

−=

Clock Port Measurement (Test Port 2):

bdsTesXsX clkcm

1)()( Eq.(2)−

=

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Eye Closure At Receiver Due to Signals At Clock and Data Ports:

)(3)2)(2)()((

)(3]2)(2][1)([)]()(1)(1)([)( Eq.(3)

sHdsTesHsclkXsdmX

sHdsTesHbdsT

esclkXsmedXstxXadsTesHsclkXsecY

•−

−=

•−−

−++−

=

Where Xclk(s) is the reference clock transfer function, Td1a is the delay from the reference clock to the data port, Td1b is the delay from the reference clock to the test port, Xtx(s) is the driver/latch 5 transfer function, and Xmed(s) is the interconnect transfer function. Where the RX PLL transfer function H2(s), and PI transfer function H3(s) are the same as those defined in the PCI Express Base Specification, Revision 2.0 with parameters that give rise to the largest eye closure Yec(s). The delay Td2 is swept from –3 ns to 3 ns – consistent with the maximum transport delay that can occur in the add-in card. 10

The two port measurement methodology is performed according to the following steps:

Data is gathered from test port 1 and test port 2 to obtain the spectrum Xdm(s) and Xcm(s) or equivalent.

The eye closure Yec(s) or Yec (t) is calculated based on equation 3. Td2 is swept from -3 ns to 3 ns. H3(s) is defined in Figure 4-21 of the PCI Express Base Specification, Revision 2.0. H2(s) is one 15 of the following values:

/ )35( 2*82.1 ), 1( 16.1

or / )38( 2*31.4 ), 3( 54.0

or / ) 3 16( 2*61.8 ), 3( 54.0:

22)(

2

2

2

222

2

222

2

sMraddB BW MHz PKdB

sMraddB BW Mhz PKdB

sMradBWdBMHzPKdBwhere

ssssH

n

n

n

nn

nn

πωζ

πωζ

πωζ

ωζωωζω

==

==

==

+++

=

Calculate the eye closure at BER=10-12 based on Yec (t). The maximum eye closure for any parameters of Td2 and H2(s) in the defined ranges is the total jitter assigned to the system board Transmitter + Transmitter interconnect + reference clock. 20

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Table 4-15: System Board Transmitter Path Compliance Eye Requirements at 5 GT/s Parameter Min Max Unit Comments VTXS VTXS_d

300 300

1200 1200

mV Notes 1, 2, 4 Notes 1, 2, 4

TTXS (with crosstalk) TTXS (without crosstalk)

95 108

ps ps

Notes 1, 3, 4

Notes: 1. All Links are assumed active while generating this eye diagram. The eye

diagram requires that CMM pattern (PCI Express Base Specification, Revision 2.0, Section 4.2.8) is being transmitted during the test using the de-emphasis level that the system board will use in normal operation. 5

2. Transition and non-transition bits must be distinguished in order to measure compliance against the de-emphasized voltage level (VTXS_d). VTXS and VTXS_d are minimum differential peak-peak output voltages.

3. TTXS is the minimum eye width. The recommended sample size for the dual port measurement is at least 106 UI. The minimum eye opening at BER 10-12 is 10 calculated based on the measured data and must not exceed TTXS. If the system board uses non-interleaved routing, then crosstalk will be present in the measured data. If the system uses interleaved routing, then crosstalk will not be present and an adjusted minimum eye width is used.

4. The values in Table 4-15 are referenced to an ideal 100 Ω differential load at the 15 end of an isolated 2-inch 85 Ω differential trace behind a standard PCI express edge finger. Exact conditions required for verifying compliance while generating this eye diagram are given in the PHY Electrical Test Considerations for PCI Express Architecture document.

A-0335

TtxS

VtxS

VtxS_d

Figure 4-12: System Board Transmitter Path Composite Compliance Eye Diagram

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The system board total jitter for the Transmitter + Transmitter interconnect + reference clock must meet the requirements in Table 4-16 when decomposed into random and deterministic jitter.

Table 4-16: System Board Jitter Requirements For 5 GT/s Signaling

Max Dj (ps) Tj at BER 10-12 (ps) With crosstalk 57 105

Without crosstalk 44 92

4.7.7. System Board Minimum Receiver Path Sensitivity Requirements at 2.5 GT/s

The minimum sensitivity values for the system board’s Receiver path compliance at 2.5 GT/s are defined in Table 4-17 and Table 4-18. A representative eye diagram is shown in Figure 4-13.

Table 4-17: System Board Minimum Receiver Path Sensitivity Requirements at 2.5 GT/s

Parameter Min Max Unit Comments VRXS VRXS_d

445 312

1200 1200

mV mV

Notes 1, 2, 5 Notes 1, 2, 5

TRXS JRXS-MEDIAN-to-MAX-JITTER

287 56.5

ps ps

Notes 1, 3, 5 Notes 1, 4, 5

Notes: 5 1. An ideal reference clock without jitter is assumed for this specification. All Links

are assumed active while generating this eye diagram.

2. Transition and non-transition bits must be distinguished in order to measure compliance against the de-emphasized voltage level (VRXS_d). VRXS and VRXS_d are differential peak-peak output voltages. 10

3. TRXS is the eye width. The sample size for this measurement is 106 UI. This value can be reduced to 274 ps for simulation purpose at BER 10-12.

4. JRXS-MEDIAN-to-MAX-JITTER is the maximum median-to-peak jitter outlier as defined in the PCI Express Base Specification, Revision 2.0. The sample size for this measurement is 106 UI. This value can be increased to 63 ps for simulation 15 purpose at BER 10-12.

5. The values in Table 4-17 are referenced to an ideal 100 Ω differential load at the end of 3-inch 85 Ω differential isolated traces behind a standard connector. The resultant values, when provided to the Receiver interconnect path of the system board, allow for a demonstration of compliance of the overall system board 20 Receiver path. The sensitivity requirements are defined and centered with respect to the jitter median. Exact conditions required for verifying compliance while generating this eye diagram are given in the PHY Electrical Test Considerations for PCI Express Architecture document.

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4.7.8. System Board Minimum Receiver Path Sensitivity Requirements at 5 GT/s

Table 4-18: System Board Minimum Receiver Path Sensitivity Requirements at 5 GT/s for a Link that Operates with 3.5 dB De-emphasis

Parameter Min Max Unit Comments VRXS VRXS_d

380 380

1200 1200

mV mV

Notes 1, 2, 3 Notes 1, 2, 3

1.5 – 100 MHz RMS Jitter 1.4 ps RMS < 1.5 MHz RMS Jitter 3.0 ps RMS 1.5 – 100 MHz DJ 30 ps PP > 100 MHz DJ 27 ps PP

Notes: 1. All Links are assumed active while generating this eye diagram.

2. Transition and non-transition bits must be distinguished in order to measure compliance against the de-emphasized voltage level (VRXS_d). VRXS and VRXS_d are differential peak-peak output voltages. 5

3. The values in Table 4-18 are referenced to an ideal 100 Ω differential load behind 3 inches of isolated 85 Ω trace and a standard PCI Express connector. After reference calibration, the reference fixture is removed and a standard PCI Express edge finger is placed into the PCI Express connector to be tested. The resultant values, when provided to the Receiver interconnect path of the system 10 board, allow for a demonstration of compliance of the overall system board Receiver path. The exact setup and methodology for injecting this signal into the Receiver interconnect path of the system board are not specified. The values in Table 4-18 may need to be adjusted based on the exact test setup and methodology. For example, if the impedance of the test setup does not create 15 the worst case mismatch that could be present with a real add-in card or the test setup does not provide crosstalk (only a single Lane is tested, etc), the values in Table 4-12 must be adjusted accordingly.

Table 4-19: System Board Minimum Receiver Path Sensitivity Requirements at 5 GT/s for a Link that Operates with 6.0 dB De-emphasis

Parameter Min Max Unit Comments VRXS VRXS_d

306 260

1200 1200

mV mV

Notes 1, 2, 3 Notes 1, 2, 3

1.5 – 100 MHz RMS Jitter 1.4 ps RMS < 1.5 MHz RMS Jitter 3.0 ps RMS 1.5 – 100 MHz DJ 30 ps PP > 100 MHz DJ 27 ps PP

Notes: 1. All Links are assumed active while generating this eye diagram. 20

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2. Transition and non-transition bits must be distinguished in order to measure compliance against the de-emphasized voltage level (VRXS_d). VRXS and VRXS_d are differential peak-peak output voltages.

3. The values in Table 4-19 are referenced to an ideal 100 Ω differential load behind 3 inches of isolated 85 Ω trace and a standard PCI Express connector. 5 After reference calibration, the reference fixture is removed and a standard PCI Express edge finger is placed into the PCI Express connector to be tested. The resultant values, when provided to the Receiver interconnect path of the system board, allow for a demonstration of compliance of the overall system board Receiver path. The exact setup and methodology for injecting 10 this signal into the Receiver interconnect path of the system board are not specified. The values in Table 4-19 may need to be adjusted based on the exact test setup and methodology. For example, if the impedance of the test setup does not create the worst case mismatch that could be present with a real add-in card or the test setup does not provide crosstalk (only a single 15 Lane is tested, etc) the values in Table 4-12 must be adjusted accordingly.

A-0336

TrxS

VrxS

VrxS_d

Figure 4-13: Representative Composite Eye Diagram for System Board Receiver Path

Compliance

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5. Connector Specification A family of PCI Express vertical edge card connectors supports x1, x4, x8, and x16 Link widths to suit different bandwidth requirements. These connectors support the PCI Express signal and power requirements, as well as auxiliary signals used to facilitate the interface between system board and add-in card hardware. This chapter defines the connector mating interfaces and footprints, as well 5 as the electrical, mechanical, and environmental requirements.

5.1. Connector Pinout Table 5-1 shows the pinout definition for the x1, x4, x8, and x16 PCI Express connectors. The auxiliary pins are identified in the shaded areas.

Table 5-1: PCI Express Connectors Pinout

Side B Side A Pin#

Name Description Name Description

1 +12V 12 V power PRSNT1# Hot-Plug presence detect

2 +12V 12 V power +12V 12 V power

3 +12V 12 V power +12V 12 V power

4 GND Ground GND Ground

5 SMCLK SMBus (System Management Bus) clock

JTAG2 TCK (Test Clock), clock input for JTAG interface

6 SMDAT SMBus (System Management Bus) data

JTAG3 TDI (Test Data Input)

7 GND Ground JTAG4 TDO (Test Data Output)

8 +3.3V 3.3 V power JTAG5 TMS (Test Mode Select)

9 JTAG1 TRST# (Test Reset) resets the JTAG interface

+3.3V 3.3 V power

10 3.3Vaux 3.3 V auxiliary power +3.3V 3.3 V power

11 WAKE# Signal for Link reactivation

PERST# Fundamental reset

5

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Side B Side A Pin#

Name Description Name Description

Mechanical key

12 RSVD Reserved GND Ground

13 GND Ground REFCLK+

14 PETp0 REFCLK-

Reference clock (differential pair)

15 PETn0

Transmitter differential pair, Lane 0

GND Ground

16 GND Ground PERp0

17 PRSNT2# Hot-Plug presence detect PERn0

Receiver differential pair, Lane 0

18 GND Ground GND Ground

End of the x1 connector

19 PETp1 RSVD

20 PETn1

Transmitter differential pair, Lane 1

GND Ground

21 GND Ground PERp1

22 GND Ground PERn1

Receiver differential pair, Lane 1

23 PETp2 GND Ground

24 PETn2

Transmitter differential pair, Lane 2

GND Ground

25 GND Ground PERp2

26 GND Ground PERn2

Receiver differential pair, Lane 2

27 PETp3 GND Ground

28 PETn3

Transmitter differential pair, Lane 3

GND Ground

29 GND Ground PERp3

30 RSVD Reserved PERn3

Receiver differential pair, Lane 3

31 PRSNT2# Hot-Plug presence detect GND Ground

32 GND Ground RSVD Reserved

End of the x4 connector

33 PETp4 RSVD Reserved

34 PETn4

Transmitter differential pair, Lane 4

GND Ground

35 GND Ground PERp4

36 GND Ground PERn4

Receiver differential pair, Lane 4

37 PETp5 GND Ground

38 PETn5

Transmitter differential pair, Lane 5

GND Ground

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Side B Side A Pin#

Name Description Name Description

39 GND Ground PERp5

40 GND Ground PERn5

Receiver differential pair, Lane 5

41 PETp6 GND Ground

42 PETn6

Transmitter differential pair, Lane 6

GND Ground

43 GND Ground PERp6

44 GND Ground PERn6

Receiver differential pair, Lane 6

45 PETp7 GND Ground

46 PETn7

Transmitter differential pair, Lane 7

GND Ground

47 GND Ground PERp7

48 PRSNT2# Hot-Plug presence detect PERn7

Receiver differential pair, Lane 7

49 GND Ground GND Ground

End of the x8 connector

50 PETp8 RSVD Reserved

51 PETn8

Transmitter differential pair, Lane 8

GND Ground

52 GND Ground PERp8

53 GND Ground PERn8

Receiver differential pair, Lane 8

54 PETp9 GND Ground

55 PETn9

Transmitter differential pair, Lane 9

GND Ground

56 GND Ground PERp9

57 GND Ground PERn9

Receiver differential pair, Lane 9

58 PETp10 GND Ground

59 PETn10

Transmitter differential pair, Lane 10

GND Ground

60 GND Ground PERp10

61 GND Ground PERn10

Receiver differential pair, Lane 10

62 PETp11 GND Ground

63 PETn11

Transmitter differential pair, Lane 11

GND Ground

64 GND Ground PERp11

65 GND Ground PERn11

Receiver differential pair, Lane 11

66 PETp12 GND Ground

67 PETn12

Transmitter differential pair, Lane 12

GND Ground

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Side B Side A Pin#

Name Description Name Description

68 GND Ground PERp12

69 GND Ground PERn12

Receiver differential pair, Lane 12

70 PETp13 GND Ground

71 PETn13

Transmitter differential pair, Lane 13

GND Ground

72 GND Ground PERp13

73 GND Ground PERn13

Receiver differential pair, Lane 13

74 PETp14 GND Ground

75 PETn14

Transmitter differential pair, Lane 14

GND Ground

76 GND Ground PERp14

77 GND Ground PERn14

Receiver differential pair, Lane 14

78 PETp15 GND Ground

79 PETn15

Transmitter differential pair, Lane 15

GND Ground

80 GND Ground PERp15

81 PRSNT2# Hot-Plug presence detect PERn15

Receiver differential pair, Lane 15

82 RSVD Reserved GND Ground

End of the x16 connector The following points should be noted:

The pins are numbered as shown in Figure 5-2 in ascending order from the left to the right, with side A on the top of the centerline and side B on the bottom of the centerline.

The PCI Express interface pins PETpx, PETnx, PERpx, and PERnx are named with the following convention: “PE” stands for PCI Express high speed, “T” for Transmitter, “R” for 5 Receiver, “p” for positive (+), and “n” for negative (-). By default, PETpx and PETnx pins (the Transmitter differential pair of the connector) shall be

connected to the PCI Express Transmitter differential pair on the system board, and to the PCI Express Receiver differential pair on the add-in card.

By default, PERpx and PERnx pins (the Receiver differential pair of the connector) shall be 10 connected to the PCI Express Receiver differential pair on the system board, and to the PCI Express Transmitter differential pair on the add-in card.

However, the “p” and “n” connections may be reversed to simplify PCB trace routing and minimize vias if needed. All PCI-Express Receivers incorporate automatic Lane Polarity Inversion as part of the Link Initialization and Training and will correct the polarity 15 independently on each Lane. Refer to Section 4.2.4. of the PCI Express Base Specification, Revision 2.0.

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If the component on the system board or add-in card does not support the optional PCI Express Lane Reversal functions, they must connect each Transmitter and Receiver Lane to the add-in card connector lanes as shown in Table 5-1. For example, a x4 component must connect Lane 0 to 0, Lane 1 to 1, Lane 2 to 2, and Lane 3 to 3.

If the component on the system board or add-in card supports the optional PCI Express Lane 5 Reversal function, it may connect each Transmitter and Receiver Lane to the add-in card connector lanes as shown in Table 5-1 or it may connect the Transmitter and Receiver lanes using a reversed Lane ordering. Either Lane ordering may be used to simplify PCB trace routing and minimize vias. However, the transmitting and receiving lanes must be connected with the same Lane ordering. For example, a x4 component may connect Lane 0 to 0, Lane 1 to 1, 10 Lane 2 to 2, and Lane 3 to 3 or it may connect Lane 0 to 3, Lane 1 to 2, Lane 2 to 1, and Lane 3 to 0.

The connectors and the add-in cards are keyed such that smaller add-in cards can be put in larger connectors. For example, a x1 card can be inserted into the x4, x8, and x16 connectors. This is referred to as up-plugging. 15

Adjacent differential pairs are separated by two ground pins to manage the connector crosstalk.

See Chapter 2 for auxiliary signals description and implementation, except the +3.3Vaux and PRSNT1# and PRSNT2# pins. The requirements for +3.3Vaux are discussed in Chapter 4 and presence detect is discussed in Chapter 3.

PRSNT1# and PRSNT2# pins are for card presence detect. One present detect pin at each end 20 of a connector guarantees that at least one of the present detect pins is last-mate/first-break. More than two PRSNT2# pins in the x4, x8, and x16 PCI Express connectors are for the purpose of supporting up-plugging. See Chapter 3 for detailed discussions on presence detect.

The sequential mating for Hot-Plug is accomplished by staggering the edge fingers on the add-in card, as shown in Section 5.2. Detailed requirements on Hot-Plug are covered in Chapter 3. 25

Power pins (+3.3V, +3.3Vaux, and +12V) are defined based on the PCI Express power delivery requirements specified in Chapter 4, with the connector contact carrying capability being 1.1 A per pin. The power that goes through the connector shall not exceed the maximum power specified for a given add-in card size, as defined in Table 4-2.

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5.2. Connector Interface Definitions The PCI Express connector outline, footprint, and the corresponding add-in card edge-finger dimensions are shown in Figure 5-1, Figure 5-2, and Figure 5-3.

Figure 5-1: Connector Form Factor

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Figure 5-2: Recommended Footprint

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Figure 5-3: Add-in Card Edge-Finger Dimensions

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The following points should be noted:

The connector has a 1.00 mm contact pitch.

The contact shall be pre-loaded, similar to the PCI connector.

The connector footprint (Figure 5-2) requires two 2.35 mm diameter location holes, working with either plastic pegs/posts or metal board locks. Metal board locks are allowed, although 5 Figure 5-1 shows only the plastic pegs on the connector housing.

Figure 5-3 defines only the mating interface related dimensions. Other add-in card dimensions are defined in Chapter 6.

The PRSNT1# and PRSNT2# pins shown in Figure 5-3 are 1 mm shorter than the other fingers. Those pins are designated as A1, B17, B31, B48, and B81, where applicable. No plating 10 tie bar is allowed underneath the PRSNT1# and PRSNT2# pins because those pins are meant to be last-mate and first-break.

As shown in Figure 5-1, an optional ridge feature is defined on the top of the connector housing on one side. This feature can be used to facilitate card retention. A retention clip may be mounted on an add-in card and latched on the ridge. 15

Two types of add-in cards must be “retention ready”:

• Graphics cards

• x1, x4, x8, or x16 I/O cards that in the judgment of the OEM or card manufacturers have sufficient weight or length that the card may need an additional retention point for stability

Retention ready means that the add-in card manufacturer must have selected (or created) a 20 retention mechanism and made provisions on the card to facilitate the retention mechanism. The reference retention mechanism designs and related component keep-out or height restriction areas are defined in the PCI Express Graphics Card Thermal Mechanical Design Guidelines.

The full-length card 321.00 mm (12.283 inches) long is considered retention ready. The mounting holes on one end of the full-length card allow the optional PCI card retainer to be 25 installed to secure the card. See Section 6.1.

Detailed connector contact and housing designs are up to each connector vendor, as long as the requirements of form, fit, and function are met.

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5.3. Signal Integrity Requirements and Test Procedures

5.3.1. Signal Integrity Requirements The procedures outlined in the following ANSI Electronics Industry Alliance (EIA) standards documents shall be followed:

EIA 364-101 – Attenuation Test Procedure for Electrical Connectors, Sockets, Cable Assemblies or Interconnection Systems EIA 364-90 – Crosstalk Ratio Test Procedure for Electrical Connectors, Sockets, Cable Assemblies or 5

Interconnection Systems EIA 364-108 – Impedance, Reflection Coefficient, Return Loss, and VSWR Measured in the Time and

Frequency Domain Test Procedure for Electrical Connectors, Sockets, Cable Assemblies or Interconnection Systems

5.3.2. Signal Integrity Requirements and Test Procedures for 2.5 GT/s Support

A common electrical test fixture is specified and used for evaluating connector signal integrity. The 10

test fixture will have .1524-mm (6-mil) wide 50-Ω single ended traces that must be uncoupled. The impedance variation of those traces shall be controlled within ±5%. Refer to the PCI Express Connector High Speed Electrical Test Procedure for detailed discussions on the test fixture.

Detailed testing procedures are specified in the PCI Express Connector High Speed Electrical Test Procedure. This document should be used in conjunction with the standard test fixture. 15

For the insertion loss and return loss tests, the measurement shall include 1.2-inch long PCB traces (0.6 inches on the system board and 0.6 inches on the add-in card). Note that the edge finger pad is not counted as the add-in card PCB trace. It is considered to be part of the connector interface. The 1.2-inch PCB trace included in the connector measurement is a part of the trace length allowed on the system board. See Section 4.6 for a discussion of the electrical budget. 20

Either single ended measurements that are processed to extract the differential characteristics or true differential measurements are allowed. The detailed definition and description of the test fixture and the measurement procedures are provided separately in a document entitled PCI Express Connector High Speed Electrical Test Procedure. An additional consideration for the connector electrical performance is the connector-to-system 25 board and the connector-to-add-in-card launches. The connector through hole pad and anti-pad sizes shall follow good electrical design practices to minimize impedance discontinuity. On the add-in card, the ground and power planes underneath the PCI Express high-speed signals (edge fingers) shall be removed. Otherwise the edge fingers will have too much capacitance and greatly degrade connector performance. A more detailed discussion on the add-in card electrical design can be 30 found in the PCI Express Connector High Speed Electrical Test Procedure.

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Table 5-2 lists the electrical signal integrity parameters, requirements, and test procedures.

Table 5-2: Signal Integrity Requirements and Test Procedures For 2.5 GT/s Support

Parameter Procedure Requirements

Differential Insertion Loss (DDIL)

EIA 364-101 The EIA standard must be used with the following considerations:

1. The step-by-step measurement procedure is outlined in the PCI Express Connector High Speed Electrical Test Procedure document (see Note 1 below).

2. A common test fixture for connector characterization shall be used.

3. This is a differential insertion loss requirement. Either true differential measurements must be made or post processing of the single ended measurements must be done to extract the differential characteristics of the connector. The methodology of doing so is covered in the PCI Express Connector High Speed Electrical Test Procedure document (Note 1).

≤ 1 dB up to 1.25 GHz; ≤ [1.6*(F-1.25)+1] dB for 1.25 GHz < f ≤ 3.75 GHz (for example, ≤5 dB at f = 3.75 GHz)

Differential Return Loss (DDRL)

EIA 364-108 The EIA standard must be used with the following considerations:

1. The step-by-step measurement procedure is outlined in the PCI Express Connector High Speed Electrical Test Procedure document (Note 1).

2. A common test fixture for connector characterization shall be used.

3. This is a differential return loss requirement. Either true differential measurements must be made or post processing of the single ended measurements must be done to extract the differential characteristics of the connector. The methodology of doing so is covered in the PCI Express Connector High Speed Electrical Test Procedure document (Note 1).

≤ -12 dB up to 1.3 GHz; ≤ -7 dB for 1.3 GHz < f ≤ 2 GHz; ≤ -4 dB for 2 GHz < f ≤ 3.75 GHz

Intra-pair Skew Intra-pair skew must be achieved by design; measurement not required.

5 ps max

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Parameter Procedure Requirements

Differential Near End Crosstalk: DDNEXT

EIA 364-90 The EIA standard must be used with the following considerations:

1. The crosstalk requirement is with respect to all the adjacent differential pairs including the crosstalk from opposite sides of the connector, as illustrated in Figure 5-4. This is reflected in the measurement procedure.

2. The step-by-step measurement procedure is outlined in the PCI Express Connector High Speed Electrical Test Procedure document.

3. A common test fixture for connector characterization shall be used.

4. This is a differential crosstalk requirement between a victim differential signal pair and all of its adjacent differential signal pairs. Either true differential measurements must be made or post processing of the single ended measurements must be done to extract the differential crosstalk of the connector. The methodology of doing so is covered in the PCI Express Connector High Speed Electrical Test Procedure document (see Note 1 below).

≤ -32 dB up to 1.25 GHz; ≤ -[32-2.4*(F-1.25)] dB for 1.25 GHz < f ≤ 3.75 GHz (for example, ≤ -26 dB at f = 3.75 GHz)

Jitter By design; measurement not required. 10 ps max

Notes: 1. The PCI Express Connector High Speed Electrical Test Procedure is available separately. 2. A typical approach to making these measurements is with a network analyzer or a TDR

oscilloscope. Differential measurements require the use of a two port (or a four port) instrument to measure the connector. The differential parameters may be measured directly if the equipment 5 supports “True” differential excitation (“True” differential excitation is the simultaneous application of a signal to one line of the pair and a 180 degree phase shifted version of the signal to the second line of the pair). If single ended measurements are made, the differential connector parameters must be derived from the single ended measurements as defined in the PCI Express Connector High Speed Electrical Test Procedure. 10

3. The connector shall be targeted for a 100 Ω differential impedance.

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In Figure 5-4, pairs marked as 11-9, 5-7, 15-13, and 17-19 are the adjacent pairs with respect to the victim pair 1-3.

OM14761

15 13 17 19

11 9 1 3

Victim PairNeed to Terminate All Ports

5 7

Figure 5-4: Illustration of Adjacent Pairs

5.3.3. Signal Integrity Requirements and Test Procedures for 5 GT/s Support

An electrical test fixture must be used for evaluating connector signal integrity. The test fixture effects, not including the connector via, are deembeded from measurements. A section is provided with test fixture requirements and recommendations. 5

Table 5-3 lists the electrical signal integrity parameters, requirements, and test procedures.

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Table 5-3: Signal Integrity Requirements and Test Procedures for 5 GT/s Support

Parameter Procedure Requirements

Differential Insertion Loss (DDIL)

EIA 364-101

The EIA standard shall be used with the following considerations:

1. The measured differential S parameter shall be referenced to an 85 Ω differential impedance.

2. The test fixture shall meet the test fixture requirement defined in Section 5.4.2.

3. The test fixture effect shall be removed from the measured S parameters. Refer to Note 1.

≥-0.5 dB up to 2.5 GHz;

≥-[0.8*(f-2.5)+0.5] dB for 2.5 GHz < f ≤ 5 GHz (for example, ≥-2.5 dB at f = 5 GHz);

≥-[3.0*(f-5)+2.5] dB for 5 GHz < f ≤ 7.5 GHz (for example, ≥-10 dB at f = 7.5 GHz)

Differential Return Loss (DDRL)

EIA 364-108

The EIA standard shall be used with the following considerations:

1. The measured differential S parameter shall be referenced to an 85 Ω differential impedance.

2. The test fixture shall meet the test fixture requirement in Section 5.4.2.

3. The test fixture effect shall be removed. Refer to Note 1.

≤ -15 dB up to 3.0 GHz;

≤ -5 dB for 3.0 GHz < f ≤ 5 GHz;

≤ -1 dB for 5.0 GHz < f ≤ 7.5 GHz

Intra-pair Skew Intra-pair skew must be achieved by design; measurement not required.

5 ps max

Differential Near End Crosstalk (DDNEXT)

EIA 364-90

The EIA standard must be used with the following considerations:

1. The crosstalk requirement is with respect to all the adjacent differential pairs including the crosstalk from opposite sides of the connector, as illustrated in Figure 5-4.

2. This is a differential crosstalk requirement between a victim differential signal pair and all of its adjacent differential signal pairs. The measured differential S parameter shall be referenced to an 85 Ω differential impedance.

≤ -32 dB up to 2.5 GHz;

≤ -26 dB for 2.5 GHz < f ≤ 5.0 GHz;

≤ -20 dB for 5.0 GHz < f ≤ 7.5 GHz

Notes: 1. The specified S parameters requirements are for connector only, not including the test fixture effect.

While the TRL calibration method is recommended, other calibration methods are allowed.

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5.3.3.1 Test Fixture Requirements

The test fixture for connecter S-parameter measurement should be designed and built to the following requirements:

The test fixture shall be an FR4-based PCB of the microstrip structure; the dielectric thickness or stackup shall be approximately .102 mm (4 mils).

The total thickness of the test fixture PCB shall be 1.57 mm (0.62”) and the test add-in card should 5 be a break-out card fabricated in the same PCB panel for the fixture.

The measurement signals shall be launched into the connector from the top of the test fixture, capturing the through-hole stub effect.

Traces between the connector and measurement ports (SMA or microprobe) should be uncoupled.

The trace lengths between the connector and measurement port shall be minimized. The maximum 10 trace length shall not exceed 45.72 mm (1800 mils). The trace lengths between the connector and measurement port on the test baseboard and add-in card shall be equal. Note that the edge finger pad is not counted as the add-in card PCB trace; it is considered as a part of the connector interface.

All of the traces on the test board and add-in card must be held to a characteristic impedance of 50 Ω with a tolerance of ±7%. 15

The test add-in card edge finger pads shall be fabricated per mechanical specification defined in Figure 5-3. The ground plane immediately underneath the edge finger pads must be removed.

The through-hole on the test board shall have the following stackup: .711-mm (28-mil) finished hole, 1.067-mm (42-mil) pad, and 1.473-mm (58-mil) anti-pad.

Use of SMA connectors is recommended. The SMA launch structure shall be designed to minimize 20 the connection discontinuity from SMA to the trace. The impedance range of the SMA seen from a TDR with a 60 ps rise time is recommended to be within 50 ±7 Ω.

If a fixture with other characteristics is used, the fixture effects must be reliably removed and must not impact measurement accuracy.

5.4. Connector Environmental and Other Requirements

5.4.1. Environmental Requirements Connector environmental tests shall follow EIA-364-1000.01, Environmental Test Methodology for 25 Assessing the Performance of Electrical Connectors and Sockets Used in Business Office Applications. The test groups/sequences and durations shall be derived from the following requirements:

• Durability (mating/unmating) rating of 50 cycles

• Field temperature: 65 °C 30

• Field life: seven years

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Since the connector defined in Section 5.2 has far more than 0.127 mm wipe length, Test Group 6 in EIA-364-1000.01 is not required. Test Group 7 in EIA-364-1000.01 is optional since the durability cycles is ≤ 50. The temperature life test duration and the mixed flowing gas test duration values are derived from EIA 364-1000.01 based on the field temperature, using simple linear interpolation. Table 5-4 lists these values. 5

Table 5-4: Test Durations

Test Duration/Temperature

Temperature Life 168 hours at 105 °C

Temperature Life (preconditioning) 92 hours at 105 °C

Mixed Flowing Gas 10 days

The low level contact resistance (LLCR) is required to be 30 mΩ or less, initially. Note that the contact resistance measurement points shall include the solder tail and the contact-mating interface, as illustrated in Figure 5-5. The resistance change, which is defined as the change in LLCR between the reading after stress and the initial reading, shall not exceed the value that is to be specified by each OEM to best suit their needs. 10

OM14762

PCI ExpressConnector

PCB

Add-inCard

ResistanceMeasurementPoints

Figure 5-5: Contact Resistance Measurement Points

To be sure that the environmental tests measure the stability of the connector, the add-in cards used shall have edge finger tabs with a minimum plating thickness of 30 microinches of gold over 50 microinches of nickel for the environmental test purpose only. Furthermore, it is highly desirable that testing gives an indication of the stability of the connector when add-in cards at the lower and upper limit of the card thickness requirement are used. In any case, both the edge tab plating thickness 15 and the card thickness shall be recorded in the environmental test report.

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5.4.2. Mechanical Requirements Table 5-5 lists the mechanical parameters and requirements. Note that the sample size shall follow Section 2.2.1 of EIA-364-1000.01.

Table 5-5: Mechanical Test Procedures and Requirements

Test Description Procedure Requirement

Visual and dimensional inspections

EIA 364-18 Visual, dimensional, and functional per applicable quality inspection plan

Meets product drawing requirements

Insertion force EIA 364-13 Measure the force necessary to mate the connector assemblies at a maximum rate of 12.5 mm (0.492 inches) per minute, using a steel gauge 1.70 mm thick with a tolerance + 0.00, - .01 mm.

1.15 N maximum per contact pair

Removal force EIA 364-13 Measure the force necessary to unmate the connector assemblies at maximum rate of 12.5 mm (0.492 inches) per minute, using a steel gauge 1.44 mm thick with a tolerance + .01, - 0.00 mm.

0.15 N minimum per contact pair

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5.4.3. Current Rating Requirement Table 5-6 lists the contact current rating requirement and test procedure.

Table 5-6: End of Life Current Rating Test Sequence

Test Order

Test Procedure Condition Requirement

1 Contact current rating

EIA 364-70 method 2 The sample size is a minimum of three mated connectors. The sample shall be soldered on a PC board with the appropriate footprint. Wire the eight power pins (B1, B2, B3, A2, A3, B8, A9, and A10) and the eight nearest ground pins (A4, B4, B7, A12, B13, A15, B16, and B18) in a series circuit. The mated add-in card is included in this circuit. The add-in card shall have 1 oz. copper traces and its mating geometry shall conform to the applicable PCI Express drawings. A thermocouple of 30 AWG or less shall be placed on the card edge finger pad (pins B2 and A9) as close to the mating contact as possible. Conduct a temperature rise vs. current test.

Mated 1.1 A per pin minimum The temperature rise above ambient shall not exceed 30 °C. The ambient condition is still air at 25 °C.

5.4.4. Additional Considerations Table 5-7 lists the additional requirements.

Table 5-7: Additional Requirements

Parameter Procedure Requirement

Flammability UL94V-1 minimum

Material certification or certificate of compliance required with each lot to satisfy the Underwriters Laboratories follow-up service requirements.

Lead-free soldering

Connector must be compatible with lead free soldering process.

Connector Color

Color of the connector should be black. Exceptions will be made for color coding schemes that call for a different color of this connector.

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This specification does not attempt to define the connector requirements that are considered application-specific. It is up to the users and their connector suppliers to determine if additional requirements shall be added to satisfy the application needs. The system level shock and vibration tests are considered application-specific because results will depend on card weight and size, chassis stiffness, and retention mechanisms, as well as the connector. Therefore those tests are not 5 specified in the connector specification. It will be up to each system OEM to decide how the shock and vibration tests shall be done.

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6. Add-in Card Form Factors and Implementation

6.1. Add-in Card Form Factors To enable the reuse of existing chassis slots, the PCI Express add-in cards are similar to the PCI add-in card form factor. Two PCI Express add-in card heights are defined: the standard height of 111.15 mm (4.376 inches) maximum and the low profile of 68.90 mm (2.731 inches) maximum. 5 Note that card height is measured from the bottom of the edge finger to the top of the card (see Figure 6-1 and Figure 6-3). Table 6-1 lists the add-in card sizes corresponding to different PCI Express Link widths.

Table 6-1: Add-in Card Sizes

Link Width Height Length

x1, x4, x84 Standard height, half length card

111.15 mm (4.376 inches) maximum

167.65 mm (6.600 inches) maximum

Standard height, full length cards

111.15 mm (4.376 inches) maximum

312.00 mm (12.283 inches) maximum5

x1, x4, x8, x16

Low profile cards

68.90 mm (2.731 inches) maximum

167.65 mm (6.600 inches) maximum

The x1 cards allow two different maximum lengths. The x1 standard height, half length card has a maximum length of 167.65 mm (6.600 inches), with applications in the mainstream desktop and 10 other platforms. The x1 standard height, full-length card allows a maximum length of 312.00 mm (12.283 inches). It is defined for applications that require more real estate than the half length card provides.

It should be noted that the maximum length specifies what the system design must accommodate. An add-in card can be any length up to the maximum for a particular Link width. For example, a x4 15 standard height card with a 177.80-mm (7.00-inch) length can be installed in a system that

4 As described in Table 4-2 a x1 add-in card that consumes more than 10 W must have a length greater than the half length card maximum. 5 Not all system designs will support this length of add-in card. It is strongly recommended that standard height add-in cards be designed with a 241.30 mm (9.5 inches) maximum length.

6

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accommodates 241.30 mm (9.5 inches) maximum length cards, but a system that only accommodates 167.65 mm (6.6 inches) maximum length cards will not support this card.

Figure 6-1 and Figure 6-2 show the standard PCI Express card form factor without and with the I/O bracket, respectively.

Figure 6-1: Standard Height PCI Express Add-in Card without the I/O Bracket

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Figure 6-2: Standard Height PCI Express Add-in Card with the I/O Bracket and Card

Retainer

The mounting holes illustrated in Figure 6-1 are required only on the right end of the full-length card (312.00 mm). Those holes are needed to install the optional PCI add-in card retainer, as illustrated in Figure 6-2.

The mounting holes and keep-out zones around them marked as note 3 in Figure 6-1 are required on those cards in which the I/O bracket is mounted to the card directly. The purpose of this keep-5 out is to ensure that the card cannot short out on the I/O bracket. On full-length cards, a keep-out of 5.08 mm is required to prevent card components from being damaged by the system’s card guides (refer to Figure 6-1).

All graphics cards are required to be retention ready as defined in Section 5.2. This retention ready requirement may also apply to x1, x4, x8, or x16 I/O cards at each OEM, or add-in card 10 manufacturer’s discretion. See Section 5.2 for more information.

Special attention shall be given to graphics cards because of their potential high mass, driven by the high power allowed. This specification defines the additional feature and keepouts for x16 graphics cards for card retention shown in Figure 6-3.

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Figure 6-3: Additional Feature and Keepouts on the x16 Graphics Card

The 3.0-mm keepout on the top of the card is to accommodate system or chassis level card retention solutions at each OEM’s discretion. To facilitate a chassis level retention solution, the height of the standard height graphics card is required to be fixed: 111.15 mm ±0.13 mm. Low profile graphics cards do not require the 3.00-mm keepout.

The “hockey stick” shaped feature and keepout defined on the bottom of the card is to allow 5 retention mechanisms either mounted directly on the system board or integrated into the x16 connector. This feature and keepout are also required for the low profile graphics card.

All retention mechanisms that are intended for the x16 graphics cards must use the feature/keepout defined in Figure 6-3. But the specific retention mechanism design is system manufacturers’ choice. Reference retention mechanism designs are given in the PCI Express Graphics Card Thermal and 10 Mechanical Design Guideline for Desktop Systems.

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Figure 6-4 shows the standard PCI Express I/O bracket, which is the same as the PCI bracket. The mounting tabs of the bracket shown in Figure 6-4 are to be mounted onto the secondary side of the card, as illustrated in Figure 6-2. However, a user also has the option to have a bracket with the mounting tabs mounted onto the primary side of the card, as depicted in Figure 6-5.

Figure 6-4: Standard Add-in Card I/O Bracket

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OM14763

Tab of Bracket Mountedon Secondary Side

CardBracket

CardBracket

Solder Side[Secondary Side]

Screw,# 4-40

Component Side[Primary Side]

STANDARD

OPTIONAL

2.84 Ref[0.112]

Screw,# 4-40

Solder Side[Secondary Side]

Component Side[Primary Side]

Tab of Bracket Mountedon Primary Side

1.27 Ref[0.050]

Figure 6-5: Bracket Design with the Mounting Tabs Mounted on the Primary Side of the Add-in Card

The PCI Express add-in card retainer is the same as the PCI card retainer, an optional feature used only with the full-length add-in cards at the maximum length of 312.00 mm (12.283 inches). Figure 6-6 shows the PCI Express add-in card retainer dimensions.

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Figure 6-6: Add-in Card Retainer

The detailed add-in card edge finger dimensions are defined in Section 5.2, which describes the connector mating interface. The edge-finger portions of the PCI Express cards are required to have bevels or chamfers as defined in Figure 5-3.

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Figure 6-7 and Figure 6-8 show, respectively, the low profile PCI Express add-in card form factor without and with the bracket, while Figure 6-9 shows the low profile add-in card I/O bracket. When mounting a low profile card into a full height PCI slot, the standard I/O bracket must be modified to add a stiffening flange. Figure 6-10 shows the modified full height I/O bracket for low profile cards. 5

Figure 6-7: Low Profile PCI Express Add-in Card without the I/O Bracket

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Figure 6-8: Low Profile PCI Express Add-in Card with the I/O Bracket

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Figure 6-9: Low Profile I/O Bracket

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Figure 6-10: Full Height I/O Bracket for Low Profile Cards

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6.2. Connector and Add-in Card Locations Figure 6-11 shows an example of a typical desktop system (microATX form factor). The add-in card slots are occupied by the PCI and AGP add-in card connectors.

PCIConnectors

OM14764

AGPConnector

Figure 6-11: Example of a PC System in microATX Form Factor

The PCI Express add-in cards will use the space allocated for those add-in card slots to take advantage of the existing chassis infrastructure. This requirement dictates that the PCI Express connectors must use the slots that coincide with the locations of the present PCI and AGP 5 slots/connectors.

Figure 6-12 illustrates the introduction of a PCI Express connector in a microATX system, co-existing with the PCI connectors. In this case, the PCI Express connector is introduced by replacing the AGP connector.

Like the PCI add-in card, the components on a PCI Express add-in card face away from the CPU, 10 or the core area.

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PCIConnectors

OM14765

PCI ExpressConnector, X16

Figure 6-12: Introduction of a PCI Express Connector in a microATX System

Over time, more PCI Express connectors will be used on the system board. Figure 6-13 shows a situation in which a basic bandwidth PCI Express connector replaces a PCI connector (x1) and a high bandwidth (x16) PCI Express connector replaces the AGP connector.

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PCIConnectors

OM14766

PCI ExpressConnector, X1

PCI ExpressConnector, X16

Figure 6-13: More PCI Express Connectors are Introduced on a microATX System Board

Figure 6-14 shows the PCI Express connector location, as well as the component height restriction zones. In this case, a x16 PCI Express connector replaces the AGP connector. When more PCI Express connectors are introduced, the height restriction zones will grow accordingly. This is depicted in Figure 6-15, where an additional x1 PCI Express connector is introduced along with the x16 connector. The 5.08 mm (0.200 inches) maximum and the 15.24 mm (0.600 inches) maximum 5 height restriction zones are identical to the PCI requirements. But the additional, small height restriction zones of 6.35 mm (0.250 inches) max are unique to PCI Express.

There is a slight offset between PCI and PCI Express connector locations. The PCI Express connectors are located slightly further away from the rear of the chassis. The PCI Express add-in cards contain features (see Note 2 in Figure 6-1 and Figure 6-7) to prevent them from being 10 mistakenly inserted into a PCI slot. Such features require the additional height restriction zones of 6.35 mm (0.250 inches) maximum.

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The card retention clip may require additional height restrictions. Such restrictions depend on the retention clip design and location, which may vary from user to user. Thus, they are not specified here as a requirement. However, in the design guideline, a reference retention clip design and implementation is given, together with the keep-out and height restriction zones.

Figure 6-14: PCI Express Connector Location in a microATX System with One

PCI Express Connector

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Figure 6-15: PCI Express Connector Location in a microATX System with Two PCI

Express Connectors

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Figure 6-16 shows the card height with respect to the top surface of the system board when assembled into a connector.

OM14767

PCB Board

PCI ExpressAdd-in Card

PCI ExpressConn, X1

16.15 Ref[0.636]

7.90 Ref[0.311]

DIM "A"

STANDARD HEIGHT

LOW PROFILE

114.55 [4.510] MAX.

72.30 [2.846] MAX.

DIM "A"

Figure 6-16: Card Assembled in Connector

6.3. Card Interoperability PCI Express cards and connectors exist with a variety of Link widths. The interoperability of cards and connectors is summarized in Table 6-2.

Table 6-2: Card Interoperability

Connector

Card

x1 X4 X8 x16

x1 Required Required Required Required

x4 No Required Required Required

x8 No No Required Required

x16 No No No Required

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Note that the connectors here refer to the receptacle connectors mounted on a system board, as defined in Chapter 5. The shaded area above the diagonal of Table 6-2 represents up-plugging, while the area below the diagonal represents down-plugging. The following points should be noted:

Down-plugging, i.e., plugging a larger edge size card into a smaller connector, is not allowed and is physically prevented. 5

Up-plugging, i.e., plugging a smaller edge size card into a larger connector, is supported.

All PCI Express add-in cards must be able to negotiate and operate in all smaller Link widths from the full Link width down to x1. The x2 and x12 Link widths are optional.

The upstream PCI Express components on a system board must be able to negotiate and operate in all smaller Link widths from the full Link width down to x1. The x2 and x12 Link 10 widths are optional.

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A. Insertion Loss Values (Voltage Transfer Function) (Informational Only)

The maximum loss values in dB (decibels) are specified for the system board and the add-in card. The insertion loss values are defined as the ratio of the voltage at the ASIC package pin (Transmitter/Receiver) and the voltage at the PCI Express connector interface, terminated by 100 Ω 5

differential termination, realized as two 50 Ω resistances. These resistances are referenced to ground at the interface (see Figure A-1).

A-0337

Add-in Card

System Board Measurement reference pointat the top of the add-in card edgefingers which have been matedwith the connector

Transmitterand Package

Transmitterand Package

Add-in CardInterconnect

System BoardInterconnectAC Coupling

Capacitor

R = 50 Ω R = 50 Ω

R = 50 Ω R = 50 Ω

Measurement reference pointat the top of the add-in card edge

finger pads. (The edge finger padsare considered part of the connector/

system board interconnect.)

PC

I Express C

onnector

Figure A-1: Example Interconnect Terminated at the Connector Interface

All PCI Express differential trace pairs are required to be referenced to the ground plane. The loss values associated with any riser card interface and adjoining connector implementation must collectively meet the system board loss budget allocations and associated eye diagrams. 10

A

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Add-in CardSystem Board

PC

I Express C

onnectorOM14768A

LST LAR

LSR LAT

Figure A-2: Insertion Loss Budgets

Table A-1: Allocation of Interconnect Path Insertion Loss Budget For 2.5 GT/s Signaling

Loss Parameter

Loss Budget Value at 1.25 GHz (dB)

Loss Budget Value at 625 MHz (dB)

Comments

PCI Express Add-in Card

LAR < 2.65 LAT < 3.84 LAR < 1.95 LAT < 2.94 Notes 1, 2

System Board and Connector

LST < 9.30 LSR < 8.11 LST < 6.00 LSR < 5.01 Notes 1, 3

Guard Band 1.25 1.25 Note 1

Total Loss LT < 13.2 LT < 9.2

Notes: 1. All values are referenced to 100 Ω, realized as two 50 Ω resistances. The loss budget

values include all possible crosstalk impacts (near-end and far-end) and potential mismatch of the actual interconnect with respect to the 100 Ω reference load.

The PCI Express Base Specification, Revision 2.0 allows an interconnect loss of 13.2 dB for 5 1.25 GHz (non de-emphasized) signals and 9.2 dB for 625 MHz (de-emphasized) signals. From this, a total of 1.25 dB is held in reserve as guard band to allow for any additional attenuation that might occur when the add-in card and system board are actually mated. The allocated loss budget values in the table directly correlate to the eye diagram voltages in Section 4.7. Tradeoffs in terms of attenuation, crosstalk, and mismatch can be made 10 within the budget allocations specified.

As a guide for design and simulation, the following derivation of the budgets may be assumed for 1.25 GHz signals: 5.2 dB is subtracted from 13.2 dB to account for near-end crosstalk and impedance mismatches. Out of this, the 1.25 dB is reserved as guard band. The following loss allocations are then assumed per differential pair: LAR = 1.4 dB; 15 LAT = 1.8 dB; LSR = 6.2 dB; LST = 6.6 dB. These allocation assumptions must also include any effects of far-end crosstalk. 625 MHz values may be derived in a similar manner.

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2. The add-in card budget does not include the add-in card edge finger or connector. However, it does include potential AC coupling capacitor attenuation on the Transmitter (TX) interconnect on add-in card. Note that the budget allocations generally allow for a maximum of 4-inch trace lengths for differential pairs having an approximate 5-mil trace width. No specific trace geometry, however, is explicitly defined in this specification. The 5 subscripts of the symbol designators, T and R, represent the Transmitter and Receiver respectively.

3. The system board budget includes the PCI Express connector and assumes it is mated with the card edge finger. Refer to Section 5.3 for specifics on the standalone connector budget. The system board budget includes potential AC coupling capacitor attenuation on the 10 Transmitter (TX) interconnect on the system board. The subscripts of the symbol designators, T and R, represent the Transmitter and Receiver respectively.

Note: The insertion loss budget distributions above are used to derive the eye diagram heights as described in Section 4.7. However, they are provided here only as a design guideline. Compliance measurements must actually be verified against the eye diagrams themselves as defined in 15 Section 4.7.

The PCI Express Base Specification, Revision 2.0 provides design guidelines for channels designed to support 5 GT/s signaling.

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Acknowledgements

The following persons were instrumental in the development of the PCI Express Card Electromechanical Specification:6

Richard Allirot Hewlett-Packard Company Gold Mao Via Technologies, Inc. Bob Atkinson Tyco International, Ltd. Bob Marshall FCI Nathan Altland FCI Steve Millard Tyco International, Ltd. Scot Baumgartner IBM Corporation Mike Miller IBM Corporation Ed Boeckmann 3Dlabs, Inc. Ltd. Dave Moss Dell Inc. Jason Bradley Intel Corporation Scott Noble Intel Corporation Jim Brewer Dell Inc. Juli Olenick Tyco International, Ltd. James Bullington 3Dlabs, Inc. Ltd. Ta-Wee Ong Molex Incorporated Jun Cao Molex Incorporated Nima Osqueizadeh ATI Technologies Inc. Raymond Chin Hewlett-Packard Company John Pescatore Dell Inc. Michael Cheong Molex Incorporated Curt Progl Dell Inc. KengYin Chok Molex Incorporated Dr. David Quint Hewlett-Packard Company Dr. Jason Chou Foxconn Electronics, Inc. Eddie Reid Intel Corporation Justin Coppin Hewlett-Packard Corporation Martha Rupert FCI Don Craven Intel Corporation Rodrigo Samper IBM Corporation Dave Davitian Tyco International, Ltd. Bill Sauber Dell Inc. Wil de Bont National Instruments Corporation Rick Schuckle Dell Inc. Richard Chiu FCI Joe Sekel Dell Inc. Karl Dittus IBM Corporation Stefaan Sercu FCI Bassam Elkhoury Intel Corporation Joanne E. Shipe Foxconn Electronics, Inc. Robert Elliot Hewlett-Packard Corporation Dave Sideck FCI Ikuo Enomoto Tyco International, Ltd. Jason Squire Molex Incorporated David Farmer 3Dlabs, Inc. Ltd. Chuck Stancil Hewlett-Packard Company Don Faw Intel Corporation John Stuewe Dell Computer Corporation Dan Froelich Intel Corporation Tom Sultzer FCI George Hayek Intel Corporation Toru Tamaki Tyco International, Ltd. Dave Helster Tyco International, Ltd. Junichi Tanigawa Tyco International, Ltd. Ted Holden Intel Corporation Clay Terry 3Dlabs, Inc. Ltd. Bob Hrehor Dell Inc. SY Theng Molex Incorporated Carl Jackson Hewlett-Packard Company Ozgur Toprakli FCI Jim Koser Foxconn Electronics, Inc. Alok Tripathi Intel Corporation Mike Krause Hewlett-Packard Company Andy Vasbinder FCI Ajay Kwatra Dell Inc. Gary Verdun Dell Inc. Tom Lanzoni Dell Inc. Andy Volk Intel Corporation Doron Lapidot Tyco International, Ltd. Clint Walker Intel Corporation Cliff Lee Intel Corporation Chris Womack Hewlett-Packard Company Mike Li Wavecrest Corporation Mike Woren Tyco International, Ltd. PT Lim Molex Incorporated Yoshisha Yamamoto Tyco International, Ltd. Yun Ling Intel Corporation Christian Yameogo Molex Incorporated Howard Locker IBM Corporation A. J. Yang Foxconn Electronics, Inc. Alan MacDougall Molex Incorporated Dave Zenz Dell Inc.

6 Company affiliation listed is at the time of specification contributions.

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